Kit of accessories for a physiological parameter monitoring device
By designing an accessory kit for the physiological parameter monitoring device, the problem of lack of charging device during repeated use of the transmitter was solved, realizing convenient charging of the transmitter and portable management of accessories, reducing costs and improving the user experience.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- BIONIME
- Filing Date
- 2025-03-05
- Publication Date
- 2026-07-14
AI Technical Summary
In existing continuous glucose monitoring systems, the transmitter, as an expensive electronic component, needs to be reused, but there is a lack of a matching charging device, making it inconvenient to carry and manage the independent and separate health management equipment.
An accessory kit for a physiological parameter monitoring device has been designed, including a closable body for storing accessories such as a transmitter, charger, and splitter. The transmitter is charged through a detachable cover on the sensing base and provides portable storage and detachment functions.
It enables convenient charging of the transmitter and portable management of accessories, reducing usage costs and improving user experience and environmental friendliness.
Smart Images

Figure CN224483979U_ABST
Abstract
Description
[Technical Field]
[0001] This utility model relates to an accessory kit for a physiological parameter monitoring device, and more specifically to a carrying container for holding accessories used in a physiological parameter monitoring device, comprising a closable body suitable for accommodating multiple accessories. The transmitter is a reusable electronic device in a continuous physiological signal measurement device used to collect and transmit physiological signals from an organism, while a charging device charges the transmitter. [Background Technology]
[0002] With advancements in technology and changes in lifestyle, many tests that previously required hospital visits are now being performed at home. The increase in chronic disease patients due to these lifestyle changes has further accelerated the development of this industry, with blood glucose measurement being one such test. Measuring blood glucose concentration is a crucial step in effectively monitoring and treating diabetes. In the past two decades, continuous glucose monitoring (CGM) systems have seen rapid development, and since CGMs must be worn for extended periods, miniaturization is an inevitable trend. Generally, the basic structure of a CGM typically includes: a sensor, a transmitter, and a sensor inserter. The sensor measures the physiological signals corresponding to glucose concentration in the body; the transmitter, usually assembled with a patch base containing the sensor, receives and transmits these physiological signals; and the implanter, typically a mechanical device, attaches the patch base containing the sensor to the skin surface, with a portion of the sensor implanted subcutaneously. The transmitter is a relatively expensive electronic component, typically containing a processing unit to process signals from the sensor and transmit them wirelessly. Ideally, a reusable transmitter would save resources, be environmentally friendly, and reduce costs. Therefore, to enable reusability, the transmitter must be powered. To avoid potential battery pollution from conventional batteries, transmitters often use rechargeable batteries. Thus, a charger compatible with the transmitter is required in this field. Furthermore, these health management devices are all independent and separate from each other. [Utility Model Content]
[0003] To overcome the problems of the prior art, this invention proposes an accessory kit for a physiological parameter monitoring device, which separately carries a charging device, a physiological signal transmitter, and necessary accessories. In use, the transmitter is detached from the patch base and inserted into the charging device for charging. When stored, the accessory kit includes a closable body for accommodating multiple accessories. The specific design of this invention not only solves the aforementioned problems but is also easy to implement. Therefore, this invention has industrial applicability. To achieve the above objectives, this invention provides an accessory kit for a physiological parameter monitoring device, which includes a sensing base, a sensor disposed on the sensing base, and a transmitter detachably covered by the sensing base. The sensing base has at least one opening, and the accessory kit includes a closable body for accommodating multiple accessories. The closable body has multiple compartments for accommodating the multiple accessories, including at least a transmitter container for storing the transmitter, a charger for charging the transmitter, and a splitter for separating the used biometric device from the transmitter, wherein the used physiological parameter monitoring device includes an analyte sensor. In a first operating state, when the closable body is open, the transmitter is removed from the transmitter container and installed onto the sensor to form the physiological parameter monitoring device for monitoring physiological parameters; in a second operating state, the splitter is removed to separate the used base from the transmitter.
[0004] According to one aspect of the present invention, an accessory kit for a physiological parameter monitoring device is provided. The physiological parameter monitoring device includes a sensing base, a sensor disposed on the sensing base, and a transmitter detachably covered on the sensing base. The sensing base has at least one opening. The accessory kit includes:
[0005] A closable body is used to store multiple accessories for the physiological parameter monitoring device, wherein: the closable body has multiple compartments for accommodating the multiple accessories, the multiple accessories including at least a transmitter container for storing a transmitter and a splitter for separating the used physiological parameter monitoring device and the transmitter, wherein the used physiological parameter monitoring device includes an analyte sensor.
[0006] In the first operating state, when the closable body is in the open state, the transmitter is taken out from the transmitter container and installed on the sensor to form the physiological parameter monitoring device for monitoring physiological parameters; in the second operating state, the splitter is taken out to separate the used sensor base from the transmitter.
[0007] Optionally, the closable body includes a first housing and a second housing, which cooperate to switch between a closed state and an open state.
[0008] Optionally, the first housing has a first outer edge and the second housing has a second outer edge, and when the closable body is in a closed state, the first outer edge and the second outer edge are engaged.
[0009] Optionally, it further includes a hinge portion connecting the first housing and the second housing, wherein the first housing and the second housing are configured to be foldable around the hinge portion.
[0010] Optionally, a cover bag is also included to surround and package the accessory kit for the physiological parameter monitoring device, making it easy to carry.
[0011] According to another aspect of the present invention, an accessory kit for a physiological parameter monitoring device is provided. The physiological parameter monitoring device includes a sensing base, a sensor disposed on the sensing base, and a transmitter detachably covered on the sensing base. The sensing base has at least one opening. The accessory kit includes:
[0012] A closable body is provided for storing multiple accessories used in the physiological parameter monitoring device, wherein: the closable body has multiple compartments for accommodating the multiple accessories, the multiple accessories including at least a transmitter container for storing the transmitter and a charger for charging the transmitter.
[0013] Optionally, the charger has a top cover and includes a top window and a slider located on the top cover for easy removal of the transmitter after charging by the user.
[0014] According to another aspect of the present invention, an accessory kit for a physiological parameter monitoring device is provided. The physiological parameter monitoring device includes a sensing base, a sensor disposed on the sensing base, and a transmitter detachably covered on the sensing base. The sensing base has at least one opening. The accessory kit includes:
[0015] A closable body is provided for storing multiple accessories used in the physiological parameter monitoring device, wherein: the closable body has multiple compartments for accommodating the multiple accessories, the multiple accessories including at least a charger for charging the transmitter, and a splitter for separating the used physiological parameter monitoring device and the transmitter, wherein the used physiological parameter monitoring device includes an analyte sensor. [Attached Image Description]
[0016] Figure 1A This is a perspective view of an embodiment of the charger of this utility model without a transmitter.
[0017] Figure 1B This is a perspective view of an embodiment of the charger of this utility model, with the transmitter already installed.
[0018] Figure 1C This is a perspective view showing an embodiment of the charger of this utility model from another angle, without the transmitter.
[0019] Figure 1D This is a perspective view showing an embodiment of the charger of this utility model from another angle, without the transmitter.
[0020] Figure 1E This is a bottom view of an embodiment of the charger of this utility model.
[0021] Figure 1F This is a rear view of an embodiment of the charger of this utility model.
[0022] Figure 1G This is a rear top view of an embodiment of the charger of this utility model.
[0023] Figure 2 This is an exploded view of an embodiment of the charger of this utility model.
[0024] Figure 3A This is a three-dimensional schematic diagram of the transmitter of this utility model during testing.
[0025] Figure 3B This is a cross-sectional view of the transmitter of this utility model along the YY direction during detection.
[0026] Figure 3C This is a cross-sectional view of the transmitter of this utility model along the XX direction during detection.
[0027] Figure 3D This is a schematic diagram showing the separation of the transmitter and sensor module in this utility model.
[0028] Figures 4A-4C This is a three-dimensional side section diagram of the present invention, showing the transmitter not yet placed on the charger, with different tangents off the center line of the charging device.
[0029] Figure 4D This is a schematic diagram of another embodiment of the stop module of the charging device of this utility model.
[0030] Figure 5A This is a side sectional perspective view of an embodiment of the charging device of this utility model, showing the transmitter placed on the charger.
[0031] Figure 5B This is a side sectional perspective view of an embodiment of the charging device of this utility model, showing the transmitter placed on the charger.
[0032] Figure 5C This is a side sectional perspective view of an embodiment of the charging device of this utility model, showing the transmitter placed on the charger, but the transmitter is hidden.
[0033] Figure 6A This is a side sectional perspective view of one embodiment of the charging device of this utility model, in which the transmitter has been fully inserted.
[0034] Figure 6B This is a side sectional view of one embodiment of the charging device of this utility model, in which the transmitter has been fully inserted into the view.
[0035] Figure 6C This is a side sectional perspective view of the present invention, which is off-center from the charging device. The sectional line passes through the stop module, and the transmitter is fully inserted, while the third electrical port protrudes completely.
[0036] Figure 6D This is a side cross-sectional view of the present invention, which is off-center from the charging device. The cross-sectional line passes through the stop module, and the transmitter is fully inserted, while the third electrical port protrudes fully.
[0037] Figure 6E This is a side sectional perspective view of the present invention, which is off-center from the charging device. The sectional line passes through the slider seat, and the transmitter is fully inserted, while the third electrical port protrudes fully.
[0038] Figure 7A This is a three-dimensional schematic diagram showing the relative positions of the charging module, the operation module, and the positioning module in one embodiment of the charging device of this utility model.
[0039] Figure 7B This is a three-dimensional schematic diagram showing the relative positions of the charging module, the operation module, and the positioning module in one embodiment of the charging device of this utility model.
[0040] Figure 7C This is a side cross-sectional view of an embodiment of the charging device of this utility model, showing the magnetic coupling between the charging module and the operation module.
[0041] Figure 8A This is a horizontal cross-sectional view of an embodiment of the charging device of this utility model, showing an embodiment with the actuator end position, wherein the transmitter is in the correct insertion direction.
[0042] Figure 8B This is a horizontal cross-sectional view of an embodiment of the charging device of this utility model, showing an embodiment with the actuator position, wherein the transmitter is inserted in the wrong direction.
[0043] Figure 9A This is a horizontal cross-sectional view of one embodiment of the charging device of this utility model, revealing another embodiment of the position of the actuating end, wherein the transmitter is in the correct insertion direction.
[0044] Figure 9B This is a horizontal cross-sectional view of one embodiment of the charging device of this utility model, revealing another embodiment of the actuation end position, wherein the transmitter is inserted in the wrong direction.
[0045] Figure 10 This is a schematic diagram of the contact points of the first conductive connector of the charging device of this utility model.
[0046] Figure 11 This is a circuit diagram of the charging device and transmitter of this utility model.
[0047] Figure 12A This is a longitudinal sectional perspective view of the storage device of this utility model.
[0048] Figure 12B This is a perspective view of the storage device of this utility model in use.
[0049] Figure 12C This is a longitudinal sectional perspective view of the storage device of this utility model, in which the sealing part has been covered and the spring has been compressed.
[0050] Figure 12D This is a longitudinal sectional perspective view of the storage device of this utility model.
[0051] Figure 12E This is a longitudinal sectional perspective view of the storage device of this utility model.
[0052] Figure 12F This is a longitudinal sectional perspective view of the storage device of this utility model.
[0053] Figure 13A This is a perspective view of an internal embodiment of the charging device of this utility model.
[0054] Figure 13B This is a perspective view of another embodiment of the charging device of this utility model.
[0055] Figure 14A This is a side cross-sectional view of another embodiment of the charging device of this utility model, in which the transmitter is not yet fully placed.
[0056] Figure 14B yes Figure 14A A side cross-sectional view of an embodiment, in which the transmitter is fully placed.
[0057] Figure 15 This is a perspective view of another embodiment of the charging device of this utility model.
[0058] Figures 16A-16B This is a three-dimensional schematic diagram of the lower front of another embodiment of the charging device of this utility model.
[0059] Figure 16C yes Figures 16A-16B A side-section schematic diagram of the action in the embodiment.
[0060] Figure 16D yes Figures 16A-16B A three-dimensional schematic diagram of the lower front of the embodiment.
[0061] Figure 16E yes Figures 16A-16B Partial exploded three-dimensional diagram of the embodiment.
[0062] Figure 17 This is a perspective view showing a kit of accessories for a physiological parameter monitoring device according to the present invention, filled with health management equipment.
[0063] Figure 18 This is a perspective view of an embodiment of the accessory kit for the physiological parameter monitoring device of this utility model, showing no health management equipment installed therein.
[0064] Figure 19 This is a perspective view of a transmitter container for housing a transmitter, according to an embodiment of the present invention.
[0065] Figures 20A-20C This is a schematic diagram illustrating the use of a splitter to separate the transmitter and the used physiological parameter monitoring device according to an embodiment of the present invention.
[0066] Figure 20D-20E This is a schematic diagram of a physiological parameter monitoring device disposed on the skin surface of an organism, according to an embodiment of the present invention.
[0067] Figure 20F This is a perspective view of the splitter according to an embodiment of the present invention.
[0068] Figure 20G This is a cross-sectional schematic diagram of the splitter according to an embodiment of the present invention.
[0069] Figure 21 This is a perspective view of another embodiment of the charger of this utility model, without the transmitter.
[0070] Figures 21A-21C This is a schematic diagram illustrating the operation steps of plugging in the cable and charging the transmitter using a charger, according to one embodiment of this utility model.
[0071] Figures 22A-22D These are schematic diagrams of other different embodiments of this utility model.
Detailed Implementation Methods
[0072] Please see Figures 1A to 1GThe diagrams, presented from different angles, fully illustrate the relative positions and connections between the components and structures. The charging device 1 is shown, comprising a body 10, typically a shell-like object, used to house and protect the required components and structures. The charging device 1 also includes a placement section 13 with a support surface 13' for holding a physiological signal transmitter 7 (hereinafter referred to as transmitter 7). The placement section 13 is similar to a slot or pocket-like structure, formed by a cover plate 10a1 engaging with the support surface 13' for lateral insertion of the transmitter 7. In other embodiments, the placement section 13 is not limited to other configurations. Figure 1B When the transmitter 7 is correctly placed in the placement section 13, the baffle 61 extends from the baffle outlet 16 to position the transmitter 7 in the placement section 13 to prevent it from falling out. Simultaneously, the electrical connector 44 (or third electrical port / connection port) also extends outside the main body 10. Figure 1A , Figure 1D The document reveals that the placement section 13 has an opening (or lifting channel) 15 for the charging base 30 of the second electrical port 3' to move up and down within it; that is, the placement section 13 is formed outside or at the top of the second electrical port 3' or the charging base 30. Furthermore, to prevent the charging base 30 from moving abnormally, a guide section 150 is also provided within the opening 15 (please refer to...). Figure 5C To prevent the charging base 30 from swaying or rotating during lifting and lowering, a groove 150' is formed between the guide portions 150. Furthermore, a first conductive connector 31, typically in the form of a gold finger, is fixed on the charging base 30 for use with… Figure 3D The first electrical port 73 of the transmitter 7 is electrically connected. Furthermore, Figure 1C and Figure 1D It is revealed that an upper limiting rib 101 is provided on the inner surface of the cover plate 10a1 within the placement part 13, and side limiting ribs 102 are provided on the inner surfaces of the two side walls of the cover plate 10a1 to reduce the contact area between the charging device 1 and the transmitter 7, thereby reducing the friction when placing or removing the transmitter 7 within the charging device 1. Furthermore, the limiting ribs also help position the transmitter 7 on the charging base, preventing the transmitter 7 from shaking or being difficult to remove. Additionally, during the production of the upper housing 10a, the limiting ribs also facilitate the demolding of the upper housing 10a from the mold. The cover plate 10a1 is used to cover the opening 15, which is beneficial for electrostatic protection and also prevents unauthorized foreign objects from contacting the first conductive connector 31 and / or the charging base 30. In another embodiment, the charging device 10 may omit the cover plate 10a1 or only moderately cover the front, sides, and top of the transmitter 7. Furthermore, the control operation module 4 (see [link to relevant documentation]) is also included. Figure 2 The push-pull button 12 extends out of the housing 10, and the user can control the operation module 4 by pushing and pulling the button 12.
[0073] Please see Figure 1DThis reveals that when the transmitter 7 is not placed in the predetermined position, such as not yet inserted or not correctly placed in the placement part 13, the actuating end 51 extends out of the placement part 13. The actuating end 51 belongs to the first locking module 5 (also known as the stop module). When the transmitter 7 is correctly placed in the placement part 13, the actuating end 51 is pressed and moves downward. The detailed operating principle will be explained later (see [link]). Figure 4C and 6C ).
[0074] Please see Figure 1E The push-pull button 12 is located at the bottom of the housing 10 and also has a positioning block 120, while the housing 10 has corresponding first positioning groove 103a and second positioning groove 103b. Figure 1E The positioning block 120 engages with the first positioning groove 103a to maintain the push-pull button 12 in the first operating state. When the user presses the push-pull button 12 into the housing 10, the positioning block 120 disengages from the first positioning groove 103a. Then, when the push-pull button 12 is pushed into the second positioning groove 103b, the positioning block 120 engages with it. (Please refer to the instructions.) Figure 6D Please see ). Figure 1F The diagram reveals a rear (tail) view of the charging device 1, showing a limiting rib 101 on the inner surface of the cover 10a1. A first mating portion 14, protruding from the deepest part of the placement portion 13, is also visible. (See also...) Figure 1G This reveals that the width W2 of the placement part 13 of the charging device 1 is less than or equal to the width W1 of the transmitter 7. When the user wants to take out the transmitter 7, he / she can easily hold and clamp the transmitter 7 from the left and right sides of the placement part 13 without clamping the charging device 1 at the same time.
[0075] Please see Figure 2 Figure 1 is an exploded view of the first embodiment of this utility model. As can be seen in the figures, the housing (body) 10 can be further divided into an upper housing 10a and a lower housing 10b. The upper housing 10a includes the previously described indicating area 11, cover plate 10a1, and placement part 13. A bearing surface 13' is formed on the placement part 13, most of which has been described previously and will not be repeated here. A second mating part 70 is formed on the transmitter 7, as described above. Figure 2 The shape of the indicator area 11 is similar to that of the second mating part 70. This design can be used to visually remind the user of the direction in which the charging device is placed. The first mating part 14 on the charging device is convex (please use it in conjunction with the first mating part 14). Figure 1F The second mating part 70 of the transmitter is concave. When the first mating part and the second mating part are combined, a foolproof structure is formed, and the first port 73 is correctly aligned with the opening 15 (not shown in the figure).
[0076] Please continue reading. Figure 2The charging device 1 includes a charging module 3, and further includes a second electrical port 3', a circuit assembly 33, and a third port 44. The second port 3' includes a charging base 30, on which a first conductive connector 31 and a second conductive connector 32 are provided. The first conductive connector 31 is typically a gold finger type connector used to transmit power and signals; the second conductive connector 32 is typically a pogo pin used for grounding. A second guide structure 301 is provided on the side of the charging base 30 as a slider, and the first slider 301 is mounted on the charging base 30 via a slider seat 302. The circuit assembly 33 is used for charging and charging control or signal transmission control of the physiological signal transmitter. One end is a circuit board 330, which includes a light-emitting component 332 and other related electronic components, and is electrically connected to the first conductive connector 31 and the second conductive connector 32. Above the light-emitting component 332, a light guide component 52' is disposed within the upper housing 10a, typically located in the first mating part 14 (please refer to the diagram). Figure 1F The indicator area 11 is typically made of transparent or semi-transparent material, or it may be part of the light guide component 52' itself. In other words, the shape of the light guide component 52' corresponds to the second mating part 70, and the indicator area 11 also serves as a light signal area. The other end of the circuit component 33 is a flexible electrical connector 331, which is usually a flexible print circuit, used to maintain an electrical connection with the electrical connector plug 44, which serves as the third electrical port, to input power. The flexible electrical connector 331 can also be replaced by a power rail conductive structure (sliding contact line).
[0077] Please continue reading. Figure 2 The charging device 1 includes an operation module 4, and further includes an operation unit 40 used to drive the charging base 30, which is electrically connected to the first electrical port 73 of the transmitter, via the second electrical port 3'. The operation unit 40 has a third electrical port 44 and a first guide structure 41, typically a slide rail or groove, coupled to the first slider 301. When the operation unit 40 is driven to move laterally, the first guide structure 41 guides the first slider 301 to move longitudinally, thereby causing the charging base 30 to move up and down. Therefore, the first slider 301 also serves as a second guide structure. Furthermore, the aforementioned push-pull button 12 is located below the operation unit 40, allowing the user to drive the operation unit 40 to move laterally via the push-pull button 12. For detailed operation instructions, please refer to the diagram. Figure 7A and 7B The push-pull button 12 and the operating part 40 can be integrally formed or they can be separate components.
[0078] Please continue reading. Figure 2The charging device 1 further includes a first locking module 5 (or stop module 5, first locking part 5) that can releasably restrict the movement of the second electrical port 3'. One end of the stop module 51 is an actuating end 51, and the other end is a stop end 52. The actuating end 51 extends into the placement part 13, i.e., protrudes from the bearing surface 13', while the stop end 52 is coupled to the blocked part 43 provided on the operating part 40. That is, the blocked part 43 is stopped by the stop end 52 and cannot move laterally. Therefore, the operating part 40 cannot guide the first slider 301 to move longitudinally through the first guide structure 41. Thus, the first locking module 5 achieves the effect of indirectly restricting the movement of the second electrical port 3'. In addition, the first locking module 5 also includes an elastic component 53, which keeps the actuating end 51 normally extended into the placement part 13 when the transmitter 7 is not placed in the placement part 13. At this time, the stop end 52 also normally stops the blocked part 43. A pivot portion 50 is provided between the actuating end 51 and the stopping end 52, and a pivot frame 10b2 is pivotally mounted on the lower housing 10b. When the actuating end 51 is pressed by the transmitter 7, the first locking module 5 can rotate with the pivot portion 50 as the rotation center and the pivot frame 10b2 as the fulcrum (for detailed front and rear operation, please refer to the diagram). Figure 4B and 5A ).
[0079] Please continue reading. Figure 2 The charging device 1 further includes a second locking module 6 (or second locking part 6, positioning module 6), which is located on the rear side of the charging device 1. It has a baffle 61 that extends from the baffle outlet 16 to reach the placement part 13, and an elastic component 62 that provides elastic force for the baffle 61 to extend out of the baffle outlet 16. The second locking part 6 also has a first connecting end 60 for connecting to the second connecting end 42. The second locking part 6 also has a guide structure 63, which is a slot coupled to the guide member 10b1 of the lower housing 10b, allowing the baffle 61 to move only in the vertical direction without shifting or rotating (for detailed operation, please refer to the diagram). Figure 4C and 6C In other embodiments, a portion of the charging module 3, operation module 4, first locking module 5, or second locking module 6 may form a housing structure similar to the lower housing 10b, together with the upper housing 10, to form an internal space to accommodate the various components (not shown). The operation module 4, first locking module 5, and second locking module 6 are collectively referred to as the control module, which controls the operation between the transmitter 7 and the charging module 3 to maintain a safe state, ensuring protection when the transmitter 7 is separated from or connected to the second electrical port 3', preventing damage to components due to improper user operation (see detailed operation instructions). Figures 4A to 6C In other embodiments, the first locking module 5 or the second locking module 6, together with the operation module 4, are referred to as the control module.
[0080] Please see Figures 3A to 3D .in Figure 3A The transmitter 7 is detachably mounted on and connected to the sensor module 81, which includes a sensing base 80 and the sensor module 81. The base 80 can be adhered to the skin S via a patch ST. In this case, the transmitter 7 is responsible for transmitting signals from the sensor 810 to the outside world. In principle, the transmitter 7 is a reusable device, while the sensor module 8 is a disposable device.
[0081] Please see Figures 3B to 3D The transmitter 7 includes a battery 71 and a first electrical port 73, and an input section 730. The input section 730 has an input terminal 732 and a secondary input terminal 733, wherein the input terminal 732 is located within a socket 731. The battery 71 provides power for the operation of the transmitter 7, such as signal output. The first electrical port 73 is a recessed structure for assembling with the transmitter assembly 81 or the second electrical port 3'. The input terminal 732 is used to electrically connect with the output terminal 812 or the first conductive connector 31. In addition, the transmitter 7 also includes a first snap-fit structure 72 for engaging and fixing with the second snap-fit structure 83 of the base 80. The sensor assembly 81 is fixed in the receiving groove 82 of the base 80. The puncture end 811 of the sensor 810 pierces the subcutaneous tissue SC, and the output end 812 of the sensor 810 enters the first electrical port 73 and is electrically connected to the input terminal 732 in the transmitter 7. Therefore, the signal measured by the sensor 810 can be transmitted to the outside world through the transmitter 7. To prevent the transmitter 7 from being installed in the wrong orientation on the base 80, the base 80 also has a mating alignment part 84 for mating with the second mating part 70. This allows the user to visually identify the installation orientation of the transmitter 7 by its structural appearance when it is placed on the base 80, thus preventing mistaken installation. The transmitter 7 described in this invention is only one embodiment; the charging device 1 of this invention can also be applied to other types of transmitters. The physiological signal transmitter 7 used in this invention generally includes a transmitter body 75, which further includes a circuit board 76, a battery 71 electrically connected to the circuit board 76, and a first electrical port 73, which is exposed externally.
[0082] Please see Figures 4A to 4D This shows the charging device 1 without the transmitter 7 being placed in it. Please refer to the numbers in the diagram for details. Figure 2 Please see. Figure 4A and Figure 4BThe charging module 3 is in the first operating state, and the operating part 40 has not yet been driven. The second electrical port 3' is located in the first position within the opening 15 (retracted relative to the bearing surface 13'), i.e., the non-charging position. The opening 15 has a groove 150'. The circuit assembly 33 is located inside the housing 10, including a circuit board 330 and an electrical connector 331. The circuit board 330 has a light-emitting component 332, and the circuit board 330 is electrically connected to the first conductive connector 31 inside the charging base 30. The electrical connector 331 is made of flexible material and is electrically connected to the electrical connector plug 44, usually soldered to the output end of the electrical connector plug 44. The indicator area 11 in front of the upper housing 10a has a light guide 11', and the rear has a baffle outlet 16, which has a baffle 61 sleeved on the guide structure 10b1. The operating part 40 is also located inside the housing 10, and its bottom has a push-pull button 12. The electrical connector plug 44 is also locked to the fixing block 40a on the operating part 40. In another embodiment, the push-pull button can also be designed with other driving methods.
[0083] Please see Figure 4A and 4B Inside the placement part 13, corresponding to the position in front of the housing 10, there is a first mating part 14, which is used to mate with the second mating part 70 of the transmitter 7 (please mate them simultaneously). Figure 1F The transmitter 7 is placed in a predetermined position. When the operation module 4 is in the first operation state, the first guide structure 41 of the operation unit 40 is coupled to the second guide structure 301 of the charging base 30, at which time the second guide structure 301 has not yet slid within the first guide structure 41. Figure 4B In this case, the first guide structure 41 is an inclined groove with a slope, thus guiding the movement of the second guide structure 301. The operating part 40 has a blocking part 43 that is locked or stopped by the stop end 52 of the first locking module 5. Therefore, when the push-pull button 12 is subjected to external force and attempts to move the operating part 40, or when the operating part 40 itself shakes, the first guide structure 41 will not move the second guide structure 301, thereby preventing the charging base 30 of the second electrical port 3' from being accidentally driven to the second position (extended relative to the bearing surface 13'). In addition, since the first conductive connector 31 is relatively thin and short, it also avoids the problem of damage to the first conductive connector 31 if the user tries to forcibly remove or place the transmitter 7. Figure 4B The location where the actuating end 51 of the first locking module 5 extends into the placement portion 13 is also revealed. A pivot portion 50 is also provided between the actuating end 51 and the stop end 52, pivotally mounted on the pivot frame 10b2 of the lower housing 10b. Therefore, the first locking module 5 is similar to a rocker structure; when the actuating end 51 is pressed down, the stop end 52 rises (see reference). Figure 5AFurthermore, the elastic component 53 connects the first locking module to the lower housing 10b and provides elasticity to the first locking module 5 to maintain the actuator 51 protruding from the bearing surface 13' when the transmitter is not inserted into the charging device 1 (i.e., when the actuator 51 is not pressed down).
[0084] Please see Figure 4C This invention reveals that when the second guide structure 301 is not driven by the first guide structure 41, the slider 302 does not move with the second guide structure 301. To prevent the charging base 30 from moving in an unexpected direction, at least one guide portion 150 is provided adjacent to the outside of the opening 15 to form a groove 150', so that the groove 150' communicates with the opening 15, allowing the slider 302 to guide the charging base 30 to rise and fall in a fixed direction from the opening 15 within the groove 150'. The second locking portion 6 also has a first connecting end 60. When the operating unit 40 is in the first operating state, the operating unit 40 is in the first position, and the first connecting end 60 engages with the second connecting end 42 on the operating unit 40 to prevent the baffle 61 from being pushed by the elastic component 62. At this time, the charging base 30 is in the first position (in a retracted state relative to the bearing surface 13'), so that the second locking part 6 is pressed down to keep the baffle 61 in the baffle outlet 16, that is, not protruding from the baffle outlet 16, so that the second locking part 6 releases the positioning of the transmitter 7, so that the transmitter 7 can be put into or taken out from the placement part 13.
[0085] Please see Figure 4DThis paper discloses another embodiment of the first locking module of the charging device of this utility model. In this embodiment, the first locking module is replaced by a locking slider 5, which has a sliding body 50, one end of which is an actuating end 51 and the other end is a stop end 52. The second guide structure 301 of the charging module 3 protrudes beyond the first guide structure 41 and is blocked above by the stop end 52. When the transmitter 7 is not placed in the placement part 13, the locking slider 5 is pushed towards the baffle 61 (i.e., the opening direction of the placement part 13) by the normal force of the spring 53. Therefore, when the second guide structure 301 is pushed upward by the first guide structure 41, it is blocked by the stop end 52 and cannot rise. Subsequently, when the transmitter 7 is inserted into the placement part 13 in the correct direction, i.e., with the second mating part 70 facing inward, the transmitter 7 can push the actuating end 51 deeper into the placement part 13, thereby causing the locking slider 5 to move in the same direction. At this time, the stop end 52 moves away from the top of the second guide structure 301. Therefore, when the user moves the first guide structure 41 by pushing and pulling the button 12, the second guide structure 301 is raised, which in turn raises the second electrical port 3', and the stop end 52 no longer blocks the second guide structure 301. As shown in the above embodiment, in addition to being decoupled from the charging module or the operating module to restrict the movement of the second electrical port 3', the first locking module may completely prohibit or only partially displace the movement of the second electrical port 3', but cannot engage with the first port 73 ( Figure 3D (This refers to a state of effective contact.)
[0086] Please refer to the following: Figures 5A to 5C The document describes the states when the transmitter 7 is placed in the predetermined position of the charging device 1 and when the operation unit 40 is controlled to drive the second electrical port 3' to extend from the support surface 13'. Please refer to the component numbers for details. Figure 2 , Figures 3A to 3D Components that overlap with those in the above diagrams will not be repeated here. Please refer to [link / reference]. Figure 5A The transmitter 7 is positioned at a predetermined location on the support surface 13'. Even when the transmitter 7 is in the correct relative position, the actuating end 51 detects whether the transmitter 7 is in the predetermined position via actuation of the transmitter 7. When the transmitter 7 is in the predetermined position, the stop end 52 releases the locking of the operating part 40, allowing the operating part 40 to drive the second electrical port 3' to move between the first position and the second position, and to connect or disconnect from the first electrical port 73. Figure 5A When the transmitter 7 is in the predetermined position, the transmitter 7 presses down the actuator end 51 to rotate the first locking module 5, and at the same time, the stop end 52 lifts up to release the stop on the blocked part 43, thereby releasing the movement restriction of the second electrical port 3'. At this time, the elastic component 53 is compressed, and when the transmitter is removed, the elastic restoring force of its elastic component 53 will drive the actuator end 51 to extend upward into the placement part 13 (e.g., Figure 4B (state).
[0087] Please see Figures 5B to 5C When the operating unit 40 is controlled to drive the second electrical port 3' to move from the first position to the second position, and when the placement unit 13 itself is inserted into the transmitter 7, and the push-pull button 12 is operated to extend a portion of the electrical connection plug 44, then... Figures 5B-5C In terms of direction, when pushed to the right, when the stop end 52 of the first locking module 5 (first locking part 5) has lifted up and no longer blocks the blocked part 43, the movement restriction of the second electrical port 3' is released, and the push-pull button 12 drives the operating part 40 to move in the same direction. At this time, the first guide structure 41 pushes the second guide structure 301 to move upward, and then drives the charging base 30 to move upward from the opening 15 and towards the first electrical port 73 of the transmitter 7 (in coordination with...). Figure 3D , Figure 6A Simultaneously, the first conductive connector 31 moves towards the socket 731 (in coordination with...). Figure 3C Simultaneously, the electrical connector 44 partially extends out of the opening 17. Furthermore, when the operating part 40 moves to the right, the second connecting end 42 disengages from the first connecting end 60 of the second locking part 6 (as shown in the image). Figure 5C Therefore, the elastic force of the originally compressed elastic component 62 can be released to push the baffle 61 out of the baffle outlet 16 and stop the tail end of the launcher 7, thereby achieving the effect of positioning the launcher 7 on the placement part 13. Please refer to Figure 5C To obscure the transmitter 7 and to more clearly depict the state of the placement part 13 itself after the transmitter 7 is inserted, and the state of the push-pull button 12 when it is operated to push out part of the electrical connection plug 44, as well as the position of the charging base 30 and its first conductive connector 31 during their ascent within the opening 15.
[0088] Please refer to the following: Figures 6A to 6D This reveals that after the transmitter is inserted, the operating unit 40 is controlled to drive the second electrical port 3' to the second position, and the electrical connector 44 has been fully extended. Please refer to the component numbers for details. Figure 2 , Figures 3A to 3D Components that overlap with those in the above diagrams will not be repeated here. Please refer to [link / reference]. Figure 6A and Figure 6B When the first locking module 5 releases the movement restriction on the operating part 40, the operating part 40 drives the second electrical port 3' to move from the opening 15 from the first position to the second position (the port is extended relative to the bearing surface 13') and electrically connect with the first port 73, i.e., it is in the charging position. The charging base 30 extends from the opening 15 and completes its connection with the input part 730, allowing the first conductive connector 31 to enter the socket 731 and electrically connect with the input terminal 732 of the transmitter 7 (e.g., ...). Figure 3C(See the indicated position). The push-pull button 12 is pushed to the front of the housing 10, which is the far right in the diagram, and the electrical connector 44 is fully extended from the opening 17. At this time, the circuit board 330 is also raised to its highest position, and the light-emitting component 332 is closest to the light guide component 52'. At this time, the light-emitting state of the light-emitting component 332 can be transmitted to the indicator area 11 through the light guide component 52', so that the overall actuation stroke has both foolproof and light-guiding effects, and effectively utilizes the internal space of the charging device 1, making the charging device miniaturized. At this time, the light-emitting component 332 is in the ready-to-light state. When the electrical connector 44 is plugged into an external power source, such as an AC power adapter, computer USB socket, car charging adapter, or device with a USB socket, please cooperate. Figure 6E The charger 1 can be plugged into a USB socket on a personal computer 91, a mobile phone charger 92, or a car cigarette light USB adapter 93, etc., so that the light-emitting component 332 can light up to provide information indication and use different light colors and modes to indicate the usage status of the charger 1.
[0089] Please see Figure 6C The operation module 4 is in the second operation state, where it can be seen that when the push-pull button 12 is pushed all the way to the front end of the housing 10, the operation part 40 also reaches the position closest to the front end of the housing 10. At this time, the second guide structure 301 is also pushed to the highest position by the first guide structure 41. Correspondingly, the electrical connection plug 44 is in... Figure 6C In the state of being released, while Figure 4C It is in a retracted state. Figure 6C It is revealed that the slide block 302 also rises to the high position of the slide groove 150', and the second connecting end 42 of the second locking part 6 (baffle 61) disengages from the first connecting end 60. Therefore, the elastic force of the elastic component 62, which was originally compressed, can be released to push the baffle 61 out of the baffle outlet 16 and stop the tail end of the transmitter 7, thereby positioning the transmitter 7 on the placement part 13. This positions and locks the transmitter 7 so that it can be removed and placed to prevent the first electrical port 73 and the second port 3' in the electrical connection from being damaged due to the accidental removal and placement of the transmitter 7. Furthermore, at this time, the second electrical port 3' is in the second position (extended relative to the bearing surface 13'), and the baffle 61 extends out of the baffle outlet 61, so that the second locking part 6 positions the transmitter 7 at the bearing surface 13' position, preventing the transmitter 7 from being put into or taken out of the placement part 13, thus protecting the first conductive connector 31 of the second electrical port 3' from damage due to improper operation of the transmitter 7. When the charging module 3 is in the third operating state, that is, when the operating unit 40 drives the second electrical port 3' to move from the second position back to the first position to separate the first electrical port 73, and the operating unit 40 presses the first connecting end 60 through the second connecting end 42 and drives the baffle 61 to descend (the operating state is as follows). Figure 4CThis causes the second locking part 6 to retract the bearing surface 13', releasing the positioning lock on the transmitter 7. Only when the first port 73 and the second port 3' are separated can the transmitter 7 be placed or removed. Please refer to... Figure 6D In one embodiment, the push-pull button 12 is located closest to the front end of the housing 10, while the positioning block 120 can simultaneously engage with the second positioning groove 103b. After charging is complete, the electrical connector 44 is first disconnected from the external power supply, and the push-pull button 12 is pressed into the housing 10 (please cooperate with...). Figure 1E (Explanation) This causes the positioning block 120 to disengage from the second positioning groove 103b. At this point, the push-pull button 12 can be pushed towards the first positioning groove 103a. Finally, the positioning block 120 returns to the first positioning groove 103a. At this time, the charging base 30 is fully lowered, and the baffle 61 returns to the baffle outlet 16 and no longer blocks the transmitter 7. The transmitter 7 can then be removed from the placement part 13. It can be seen that the operation of the push-pull button 12, combined with the positioning method between the positioning block 120 and the first positioning groove 103a and the second positioning groove 103b, can reduce the frictional wear between the opening 17 and the first electrical port 73 and the second electrical port 3' caused by improper operation or accidental movement or shaking, thereby improving the durability of the overall operating structure of the charging device 1. In another embodiment, the sliding design of the push-pull button does not require the action of pressing it into the housing 10.
[0090] Please refer to the following: Figure 7A and 7B Please refer to the component numbers for details. Figure 2 And other illustrative diagrams, in which the housing 10 is removed to fully reveal the relative positions and connections between the operation module 4 and the charging module 3. Figure 7A In the first operating state of this utility model, the second guide structure 301 is located in the first position within the first guide structure 41, usually at a lower position, so that the charging base 30 of the second electrical port 3' is kept in a retracted position relative to the bearing surface 13'. As can be seen from the previous figures and description, the charging base 30 can only move up and down. Therefore, in order to avoid the charging base 30 from accidentally moving up and down due to up and down shaking, thereby driving the operating module 4, the first guide structure 41 of this utility model is a guide groove structure, and a first transverse groove 41a is further extended in the first position. Its extension direction is perpendicular to the movement direction of the second guide structure 301. Therefore, when the charging module 1 shakes parallel to the movement direction of the charging base 30, the first transverse groove 41a, because its extension direction is perpendicular to the movement direction of the second guide structure 301, can prevent the charging base 30 from moving due to the shaking. Figure 7BIn the second operating state, the operating part 40 is pushed forward, causing the second guide structure 301 to be positioned in a second position within the first guide structure 41, typically at a higher position, so that the charging base 30 remains in a protruding position opposite to the supporting surface. In this invention, the first guide structure 41 extends further in the second position to form a second transverse groove 41b, the extension direction of which is perpendicular to the moving direction of the second guide structure 301, to prevent the charging base 30 from moving due to wobbling parallel to its moving direction. Please continue. Figure 7A and Figure 7B and cooperate Figure 2 The first conductive connector 31 and the second conductive connector 32 are inserted into the circuit board 330, and Figure 7B Charging module 3 ( Figure 2 It is already in a rechargeable state.
[0091] Please see Figure 7C This is a side sectional view of another embodiment of the charging module and operation module of this utility model. It shows that the baffle 61 is directly connected to the charging base 30 via the connector 6', making their lifting and lowering completely synchronized. The charging base 30 can also be integrally formed with the baffle 61 and the connector 6'. In other words, the charging module 3 can be integrally formed with the baffle 61, which serves as the second locking module. The operation module 4 and the charging module 3 are magnetically coupled. The charging module 3 has a first magnetic component MP1 below it, while the operation module 4 has a second magnetic component MP2 and a third magnetic component MP3 on top. The first magnetic component MP1 and the second magnetic component MP2 are repulsive, while the first magnetic component MP3 is attracted. Therefore, when the operation module 4 is in the second operating state (pushed all the way to the right), the second magnetic component MP2 is below the first magnetic component MP1, pushing the charging module 3 upward through repulsion, and simultaneously causing the baffle 61 to extend upward out of the baffle outlet 16. In addition, when the operation module 4 is in the first operation state (pushed to the left), the third magnetic component MP3 is located below the first magnetic component MP1, and pulls the charging module 3 downward by attraction, and at the same time drives the baffle 61 to retract downward to the baffle outlet 16.
[0092] Please refer to the following: Figures 8A to 9B Please refer to the component numbers for details. Figure 2 And other diagrams. Components and actions that overlap with those in the above diagrams will not be repeated here. Please refer to... Figure 8A and Figure 9A These are all top cross-sectional views of the charging module of this utility model in its usage state with the transmitter installed. It can be seen that the transmitter 7 is placed on the placement part 13, and the second mating part 70 mates with the first mating part 14, so that the transmitter 7 is in the correct relative position or predetermined position. At this time, the first port 73 is aligned with the opening 15. Therefore, when the charging base 30 (please mate with...) Figure 6A When raised, it can correctly connect to the first port 73 electrically. Figure 8A and Figure 8B The position of the actuating end 51 is approximately equal to the position of the first mating part 14 in the lateral direction. Therefore, the actuating end 51 can only be pressed to make the first locking module 5 rotate and stop blocking the blocking part 43 when the transmitter 7 reaches the end of its stroke (see reference). Figure 5A The actuating end 51 is located at the end of the bearing surface 13' to reduce friction with the bottom of the transmitter 7. In other embodiments, the actuating end 51 is not limited to other locations. Furthermore, since the first mating part 14 is a protruding structure extending into the placement part 13 (e.g., Figure 1F As shown), a recessed area is naturally formed on both sides of the transmitter 7, and the actuating end 51 is located in this recessed area. Conversely, the second mating part 70 of the transmitter 7 is an inwardly recessed structure, thus protruding structures are formed on both sides of the second mating part 70. Therefore, when the second mating part 70 is mated with the first mating part 14, the two protruding structures on both sides of the second mating part 70 will enter the recessed area, thereby causing the protruding structures to touch the actuating end 51, causing the stop end 52 to lift up and no longer block the blocked part 43. At this time, the baffle 61 can extend from the baffle outlet 16 to block the bottom surface of the tail end of the transmitter 7, thereby achieving the effect of locking the transmitter 7. Figure 8B In this configuration, when the transmitter is inserted into the charger 1 in the wrong direction, if the tail end of the transmitter 7 enters the placement part 13, it is blocked by the first mating part 14. The front end of the transmitter 7 presses against the baffle 61, preventing the baffle 61 from extending out of the baffle outlet 16. Furthermore, the first electrical port 73 is not aligned with the opening 15. Simultaneously, because the tail end of the transmitter 7 cannot reach the end of the insertion stroke, the transmitter 7 cannot press against the actuating end 51, and therefore the stop end 52 continues to block the blocked part 43. Thus, the operating part 40 cannot move, and the charging base 30 cannot protrude from the top surface of the opening 15. This prevents the first conductive connector 31 from abnormally colliding with the transmitter 7 and potentially damaging it, thereby extending the service life of the charging device 1. In other words, this is a safe state, preventing the first conductive connector 31 on the second electrical port 3' from impacting the transmitter 7. At this time, the second connecting end 42 also restricts the first connecting end 60, preventing the baffle 61 from extending. This phenomenon also serves as a reminder to the user that the transmitter 7 has been placed in the wrong direction.
[0093] Please see Figure 9A and Figure 9B Compared to Figure 8A and Figure 8B The actuating end 51 is located away from the recessed area. During the placement of the transmitter 7, the two protruding structures first press down on the actuating end 51, causing the stop end 52 to lift up and no longer obstruct the blocked part 43, before entering the recessed area to engage with the first mating part 14. The baffle 61 can then extend from the baffle outlet 16 to block the tail end of the transmitter 7. Figure 9BWhen the transmitter is inserted into the charger 1 in the wrong direction, the transmitter 7 enters the placement part 13 with its tail end, causing the bottom front end of the transmitter 7 to press against the baffle 61, preventing the baffle 61 from extending out of the baffle outlet 16. At the same time, although the transmitter 7 can touch the actuating end 51 and cause the stop end 52 to lift up and no longer block the blocked part 43, the movable distance of the operating part 40 is controlled so that the first conductive connector 31 cannot be exposed from the top surface of the opening 15, so as to prevent damage to the bottom of the transmitter 7 and the first conductive connector 31 due to improper operation. At this time, only a part of the electrical connection plug 44 can be pushed out, so it can still serve as a reminder to the user that the transmitter 7 is placed in the wrong direction. That is, this is a safe state to prevent the first conductive connector 31 on the second electrical port 3' from hitting the transmitter 7.
[0094] Please refer to the following: Figure 10 This is a schematic diagram of the contact points of the first conductive connector of this utility model. The first conductive connector 31 is presented as, but is not limited to, a gold finger-shaped contact point, and the configuration of the contact end 310 of the first conductive connector 31 is the same as the configuration of the sensor output end 812 (e.g., Figure 3B-3D As shown), both the contact terminal 310 and the output terminal 812 can be inserted into the socket 731 of the first electrical port 73 of the transmitter 7. Therefore, the first conductive connector 31 can share the first electrical port 73 with the output terminal 812 to save internal space in the transmitter 7. Please continue reading. Figure 10 And see also Figure 11 , Figure 11 This is a circuit diagram of the charging device and transmitter of this utility model. It shows that the circuit assembly 33 within the charger 1 includes a charging circuit group 1A and a calibration circuit group 1B. The first conductive connector 31 has, but is not limited to, eight contacts 310: BAT, SW, RX, TX, E1, E2, E3, and E4, which can be adjusted to match the number of contacts at the sensor output terminal 812. The charging circuit group 1A is electrically connected to the third electrical port 44 to input power. The charging circuit group 1A provides and controls the charging voltage. The charging circuit assembly 1A then charges the transmitter 7 through contact BAT, outputting the charging voltage to charge the transmitter 7. Contact SW acts as a charging switch. The remaining contacts are used to connect the calibration circuit group 1B of the charging device 1 to the sensing module 74 of the transmitter 7, facilitating transmitter function detection, including data transmission, control detection self-calibration, leakage current measurement, and / or resistance measurement. In another embodiment, the charging device 1 may only provide a charging function.
[0095] Please see Figures 12A to 12F in Figure 12AThe moisture-proof component 2 is disclosed, having a shell 20 generally in the shape of a can, such as a cylindrical, elliptical cylindrical, or flat cylindrical can, for accommodating the charging device 1 or transmitter 7, or a charging device 1 containing a transmitter 7, to form the moisture-proof component 2. The moisture-proof component 2 also has an opening 23', with a first snap-fit edge 23 formed beside the opening 23', and the opening 23' having an opening direction perpendicular to the opening 23', while the protruding direction of the first snap-fit edge 23 is perpendicular to the opening direction. A cover 24 is movably disposed on the shell 20 and used to seal the opening 23'. A second snap-fit edge 25 is also formed on the inner side of the cover 24, its protruding direction relative to the first snap-fit edge 23 so that the two interlock. Furthermore, the housing 20 contains an elastic component 22. When the charging device 1 is placed inside the housing 20 and the cover 24 seals the opening 23', the charging device 1 is pressed and retracted into the housing 20 by the cover 24, thereby causing the elastic component 22 to undergo elastic deformation (please refer to...). Figure 12C When the cover 24 is opened, the spring-loaded component 22 releases its elastic potential energy, pushing the charging device 1 out, causing at least a portion of the charging device 1 to protrude out of the housing, making it easier for the user to remove (e.g., Figure 12B When the transmitter 7 requires charging, the charging device 1 is removed from the housing 20 to connect to an external power source for charging. The elastic component 22 can be a compression spring, such as a conical spring, coil spring, or helical spring. The elastic component 22, through its interference relationship with the charging device 1, can also serve to fix the position of the accessory within the container, preventing shaking. Figure 12C A conical spring was used. Because the diameter of each coil in the conical spring increases significantly from top to bottom, therefore, when... Figure 12C The cover 24 seals the opening 23', thus pressing the charging device 1 into the housing 20. When the charging device 1 compresses the elastic component 22, the previous spring coil can be pressed into the next spring coil. Therefore, compared to a typical cylindrical coil spring, it can be compressed to a shorter length, which helps reduce the volume of the moisture-proof component. When the charging device is in the inserted state, the spring compression height Hcompress plus the charging device length H1 is less than the housing height H2. When the charging device is in the removed state, the spring extension height Hextend plus the charging device length H1 is greater than the housing height H2. Please continue reading. Figure 12A and 12CThe housing 20 is further divided into a first accommodating space 20' and a second accommodating space 21. The first accommodating space 20' is used to store the charging device 1, while the second accommodating space 21 is used to contain the desiccant 29. A perforated structure 28 separates the two spaces, allowing moisture in the first accommodating space 20' to pass through the perforated structure 28 to reach the second accommodating space 21, where the desiccant 29 absorbs the moisture, thus preventing the transmitter 7 from getting damp. The transmitter 7 disclosed in the first embodiment is approximately 32.8 mm * 19.8 mm * 4.15 mm (+ / - 0.5 mm), and the charging device 1 is approximately 40 * 26 * 23 mm (+ / - 0.5 mm). The transmitter is mounted on the charger, and the volume of the moisture-proof component 2 is no greater than 200 cubic centimeters, or between 12 and 138 cubic centimeters, or between 25 and 100 cubic centimeters, or between 30 and 70 cubic centimeters. Its diameter is designed to be between 2 and 5 cm, or its length multiplied by its width is controlled to be between 3 and 28 cm, and its height is designed to be between 4 and 7 cm, so that the size of the moisture-proof component is minimized and convenient for users to carry.
[0096] Please see Figures 12D to 12F This discloses other embodiments in which the transmitter 7 is placed within the moisture-proof assembly 2. Figure 12D The document reveals a configuration where only the emitter 7 is placed within the moisture-proof assembly 2, which has a perforated structure 28. A desiccant 29 is also disposed within the housing 20, for example, at the bottom. Figure 12E This reveals that the elastic component 22 is directly disposed at the bottom of the housing 20, and the desiccant 29 is also disposed inside the housing 20. Alternatively, the desiccant 29 can be selectively disposed on the inner surface of the cover 24, so that when the housing 20 is opened, the desiccant 29 faces outwards for easy replacement. As for... Figure 12F This reveals that only the transmitter 7 is placed inside the moisture-proof component 2 with the perforated structure 28. In another embodiment, the desiccant 29 can be integrally formed into the housing or inner wall, so that the housing 20 does not need to distinguish different accommodating spaces (not shown). In addition, the push-fit part 27 facilitates the user to open the cover 24. The moisture-proof component 2 can properly protect and isolate the charging device 1 from external moisture when it is not in use, and further utilizes the internal desiccant to dehumidify the transmitter 7 and / or charging device 1 to extend its service life and prevent moisture from damaging electronic components. The housing 20 can also have a structure similar to the observation area 21', which is a part (partial) of the housing injected with transparent or translucent material. If a moisture-absorbing and color-changing desiccant is used or an additional drying indicator component (not shown) is provided, the moisture status of the transmitter 7 and / or charging device 1 can be easily viewed.
[0097] The method of using the moisture-proof component 2 is as follows: A first transmitter and a second transmitter are provided to the user simultaneously. The first moisture-proof component includes the first transmitter and the moisture-proof component 2. The second moisture-proof component includes a second transmitter combined with a charging device and placed inside the moisture-proof component 2. The user first uses the first transmitter to perform a measurement. When the battery level of the first transmitter drops to a minimum value, it is removed from the base, and the second transmitter and charging device 1 are removed from the moisture-proof component 2. The second transmitter is used to install on the base, while the first transmitter is placed in the placement part 13 of the charging device 2 to charge. After charging is complete, the first transmitter and charging device assembly are placed back into the moisture-proof component 2 for storage, allowing the first and second transmitters to be charged and used alternately. The moisture-proof component 2 used for the first transmitter can be any type of container.
[0098] Please see Figure 13A This is another embodiment of the charging device of this utility model, and please cooperate with it. Figure 2 Unlike previous embodiments, the charging device 1 electrically connects the third electrical port (USB socket 44') and the circuit board 330 of the second port 3' via a wire 331'. The wire 331' also has a certain degree of flexibility to accommodate the bending and lowering of the charging module 3. Furthermore, Figure 13A The difference from the previous embodiment is that its third electrical port is replaced by a USB socket 44' instead of the electrical connector plug 44 (USB plug), and it also forms a power storage unit 45 with the rechargeable battery 46 and the power circuit board 47. The power storage unit 45 is electrically connected to the charging module 3 to input power to charge the transmitter 7. Furthermore, the user can connect the USB socket 44' to an external power source to repeatedly replenish the power to the rechargeable battery 46, increasing ease of use. In another embodiment, the power storage unit 45 can omit the USB socket and use a disposable battery, such as a commercially available dry cell battery or button cell battery. In another embodiment, the rechargeable battery 46 can also be omitted, and the USB socket 44' can be connected to an external power source 9 (… Figure 13B ,as well as Figure 6E The transmitter 7 is powered by the numbers 91, 92, and 93. Figure 2 Although the operation section 40 of the operation module 4 shown is not in Figure 13A While disclosed, this feature is still used in this embodiment, but it is not shown in this figure because it would obscure the power storage unit 45. The connection and linkage between the operation unit 40 and the second electrical port 3' of the charging module 3 are mainly through the coupling between the first guide structure 41 and the second guide structure 301, and their operational relationship is as described above. However, unlike the previous embodiment, Figure 13A , Figure 13BThe operating part 40 is not fixed to the USB socket 44' (third electrical port). Instead, the USB socket 44' is only fixed inside the charging device 1, and the socket hole of the socket 44' is exposed. Therefore, when the push-pull button 12 is operated, it will only drive the second guide structure 301 through the first guide structure 41, while the USB socket 44' will not move. Figure 13A For the functions of other components, please refer to the previous diagrams and explanations, which will not be repeated here.
[0099] Please see Figure 13B This is another embodiment of the charging device of this utility model, and please refer to it for further information. Figure 2 , Figure 13B and Figure 13A The biggest difference in the embodiment is that the power storage unit 45 connects the power circuit board 47 to the circuit board 330 of the charging dock 30 via a coiled wire 331". Essentially, it still uses a push-pull button 12 on the charging device 1. Figure 13B The displacement (not shown) causes the charging base 30 and circuit board 330 of the second electrical port 3' to rise and fall, thereby indirectly causing the coiled wire 331" to extend and retract. In another embodiment, the coiled wire 331" can also be replaced by a spring connector (POGO pin). For the functions of other components, please refer to the previous diagrams and descriptions, which will not be repeated here. Figure 13A and 13B The USB socket 44', which serves as the third electrical port, is designed to be so that it does not need to be moved back and forth.
[0100] Please see Figure 14A and 14B This discloses another embodiment of the charging device. The charging device 1 includes a placement portion 13 for placing a transmitter 7, the placement portion 13 further including a support surface 13' for holding the transmitter 7, and the support surface 13' including an opening 15 (…). Figure 4A On the opposite side of the bearing surface 13', two charging modules 3 are arranged, including a second electrical port 3', a circuit assembly 33, and a third electrical port 44. The second electrical port 3' is configured in the opening 15 (see [reference]). Figure 4A Within, for use with the first electrical port 73 (see also...) Figure 3D For electrical connection, the third electrical port 44 is used to connect to an external or internal power source (please refer to the instructions). Figure 6E Reference numbers 91, 92, 93 or see Figure 13B (Ref. 46), Circuit component 33 (please refer to) Figure 2The second electrical port 3' and the third electrical port 44 are connected for charging and charging control of the physiological signal transmitter 7. A control module is also provided on the opposite side of the bearing surface 13' to control the safe operation between the transmitter 7 and the charging module 3. This module includes an operation unit 40, which drives the second electrical port 3' to electrically connect with the first electrical port 73. A first locking part 5 is also provided on the opposite side of the bearing surface 13', which can release the electrical connection between the second electrical port 3' and the first electrical port 73, or further, can release the displacement of the second electrical port 3'. For details on the operation of the first locking part 5, please refer to [reference needed]. Figure 4B , 5A The explanation for 6B is omitted here. Please refer to [link / reference]. Figure 14A and 14B A second locking part 61 is provided on the bearing surface 13' at the other end opposite to the indicating area 11. This locking part is retractable on the bearing surface 13' to fix the position of the transmitter 7. Furthermore, the second locking part 6 includes a baffle 61, which is sleeved on the guide rod 10b3 and can move vertically. It is connected to the lower part of the bearing surface 13' via a spring 62', and the spring force provided by the spring 62' keeps the baffle 61 normally protruding from the bearing surface 13'. See also... Figures 14A to 14B When the transmitter 7 is placed on the support surface 13', during the placement process, the transmitter 7 will first press the baffle 61 into the support surface 13'. After the first mating part 14 and the second mating part 70 engage, the transmitter 7 will just move away from the top of the baffle 61 and no longer obstruct it. At this time, the baffle 61 will be pushed out of the support surface 13' again by the elastic restoring force of the spring 62'. When you want to remove the transmitter 7, first push the push-pull button 12 to the left to lower the charging base 30 to disconnect the electrical connection. Then, simply press the baffle 61 into the support surface 13' so that it no longer obstructs the tail of the transmitter 7, and the transmitter 7 can be moved to the left to move away from the support surface 13' and the placement part 13. Figure 14A and 14B The features of the second locking part 6 shown can also be applied to other embodiments of the charging device of this utility model, such as... Figure 1A In other words, the baffle 61 retracted under the support surface 13' can be regarded as being pressed down by the user to facilitate the insertion of the transmitter 7 into the placement part 13, and the user can also... Figure 14A As shown, the baffle 61 is pressed down directly by the transmitter 7. During the placement process, if the second mating part 70 is correctly inserted inward into the placement part 13 to mate with the first mating part 11 so that the transmitter 7 is in the correct relative position, then the baffle 61 will no longer be blocked by the transmitter 7 because the transmitter 7 has reached a deeper position in the placement part 13, and can be supported by the elastic component 62. Figure 2 , Figure 5BThe restoring force pushes it back out onto the bearing surface 13'. Therefore, it can be seen that if... Figure 14A and Figure 14B If the baffle 61 is removed, the first connecting end 60 of the second locking part 6 and the second connecting end 42 of the operating part 40 can be eliminated.
[0101] Please see Figure 15 The embodiment without cover plate 10a1 is disclosed. Therefore, the bearing surface 13' itself serves as the placement part, and an indicator area 11 is provided at one end of the bearing surface 13' as a first mating part, which can provide a visual prompt so that the user can connect, mate, and engage the second mating part 70 with it. The first locking module 5 ( Figure 2 , Figure 4B The actuating end 51 ( Figure 1D , Figure 1F , Figure 2 , Figure 4B It also protrudes from the bearing surface 13'. Furthermore, a baffle outlet 16 is provided at the other end of the bearing surface 13', and the baffle 61 ( Figure 2 , Figure 4C , Figure 5C The transmitter 7 is located therein. Since there is no cover plate 10a1 in this embodiment, to prevent the transmitter 7 from detaching upwards (i.e., along the axis of the bearing surface 13'), a similar [feature / feature] is provided on the bearing surface 13'. Figure 3D The second latching structure 83 on the base 80 shown is used to interlock with the first latching structure 72 of the transmitter 7, thus securing the transmitter 7 to the support surface 13'. Furthermore, to ensure the transmitter 7 is more securely attached to the support surface 13' and will not detach due to accidental impact, side walls 102' are formed on the support surface 13'. These side walls are typically arranged in pairs, located on both sides of the support surface 13'. When the transmitter 7 is secured to the support surface 13', the side walls 102' fit against the sides of the transmitter 7, thus assisting in securing the transmitter 7 in the lateral direction. The functions of other components are also described in the previous diagrams and explanations, and will not be repeated here.
[0102] Please see Figures 16A to 16BThis is another embodiment of the charging device. Except for the components and structures such as the press button 12', the stop end 52 and the avoidance notch 52' of the first locking module 5, which differ from the embodiments in the previous figures, the remaining components and structures are the same as before. The second port 3' (or charging base 30) is a rising and falling movement mechanism. Therefore, in this embodiment, the second port 3' is connected to the press button 12' to drive the raising and lowering of the charging base 30. It is typically a latch button structure. The press button 12' can also be part of the charging module 1 or an independent operating component. When pressed once, the charging base 30 rises and locks; when pressed again, it unlocks and returns to its original position, i.e., the position when not pressed. Simultaneously with the operation of the press button 12', the second slider 302 of the charging base 30 also slides up and down between the two guide portions 150. Alternatively, the press button 12' can be positioned using the positioning button 180, which will be explained in detail later. Please refer to... Figure 16A This reveals that the transmitter 7 has not yet been inserted into the placement part 13, therefore, at this time, the actuating end 51 of the stop module 5 is also inserted into the placement part 13 (please refer to...). Figure 1D If button 12' is pressed into the main body at this time, the stop end 52 will block the blocked part 43, thereby preventing the charging base 30 from entering the placement part 13. In another embodiment, the blocked part 43 may also be formed on the charging base 30 (not shown), or in yet another embodiment, a method such as... Figure 4D Locking slider 5. See also Figure 16B This reveals that the transmitter 7 has been inserted into the placement section 13. Therefore, the actuating end 51 is pressed down by the transmitter 7, causing the first locking module 5 to rotate so that the dodging notch 52' aligns with the blocking part 43. In other words, the stop end 52 moves away from the top of the blocking part 43. If the pressing button 12' is pressed into the main body at this time, the blocking part 43 can continue to rise through the dodging notch 52', allowing the charging base 30 to enter the placement section 13. When the pressing button 12' moves inward, the stop end 52 enters the dodging space 43' to avoid interference with the pressing button 12'. Furthermore, as... Figure 16C and 16D As shown, the pivot bracket 10a2 of the upper housing 10a and the pivot bracket 10b2 of the lower housing 10b together rotatably clamp the pivot portion 50 of the first locking module 5. The lower housing 10b also has a blocking structure 10b3 to prevent the movement of the stop end 52, so as to prevent the actuating end 51 from excessively extending into the placement portion 13. The charging device 1 also includes a second locking module 6, which has a positioning portion 61 and is connected to the elastic unit 62 (such as... Figure 5C , Figure 6A Therefore, the support surface 13' can be extended vertically to lock the installation position of the physiological signal transmitter 7.
[0103] Please see Figure 16ETo allow for full observation of the relationship between the positioning button 180 and the positioning groove 10b3, the positioning button 180 has been moved from inside the positioning groove 10b3 to the top. The positioning groove 10b3 contains a pair of first positioning blocks 10b31 and second positioning blocks 10b32. The first positioning block 10b31 is positioned below the first state position 10b31p, which is the position when the press button 12' is at its lowest point. The first positioning block 10b31 blocks the positioning shoulder 180a, thus preventing the positioning button 180 from moving upwards, thereby preventing the press button 12' from moving upwards. The second positioning block 10b32 is positioned above the second state position 10b32p, which is the position when the press button 12' is at its highest point. The second positioning block 10b32 blocks the positioning shoulder 180a, thus preventing the positioning button 180 from moving downwards, thereby preventing the press button 12' from moving downwards. Furthermore, to move the press button 12' from the first state position 10b31p to the second state position 10b32p, simply press the positioning button 180 inward to bend the elastic structure 180c and align the channel 180b with the first positioning block 10b31 and the second positioning block 10b32. Then, the press button 12' can be operated, or the positioning button 180 can be pushed upward. At this time, each positioning block (10b31, 10b32) passes through the channel 180b relative to each other without being obstructed by the positioning shoulder 180a. Similarly, to return the press button 12' to the lowest position, i.e., the first state position, press the positioning button 180 inward to bend the elastic structure 180c and align the channel 180b with the second positioning block 10b32 and the first positioning block 10b31. Then, push the positioning button 180 downward, thereby moving the press button 12' back to the first state position. Furthermore, a return component (not shown in the figure, but may be an elastic component or a magnetic component) may also be provided between the press button 12' or the second electrical port 3' and the upper housing 10a or the lower housing 10b. That is, when the press button 12' is pressed, the second electrical port 3' is electrically connected to the first electrical port 73, which gives the return component a potential energy. The press button 12' then relies on the positioning shoulder 180a to abut against the second positioning block 10b32 to resist this potential energy. When the positioning button 180 is pressed inward and the channel 180b is aligned with the second positioning block 10b32, the positioning shoulder 180a is no longer blocked by the second positioning block 10b32, which also releases the potential energy, thereby allowing the press button 12' to return to its initial position.
[0104] Those skilled in the art will understand the foregoing description of this utility model. Figure 2 As can be seen from the various embodiments, the charging module disclosed in the charging device 1 can operate independently in conjunction with the transmitter 7, or the charging module can be used separately in conjunction with the operation module (e.g. Figure 4A (operating unit), or used in conjunction with the first locking module (such as...) Figure 4B , 4DThe first locking part 5 or the locking slider 5), or used in conjunction with the second locking part (such as... Figure 4C Or the baffle 61 of 14A is connected by connector 61' ( Figure 7C (and the second electrical port 3' is linked); or the charging module 3 is used in conjunction with the operation module 4 and the first locking module 5 (e.g.) Figure 4B The operation unit 40 and the first locking unit 5); or the charging module 3 is used in conjunction with the operation module 4 and the second locking unit 6 (e.g. Figure 4C The operation unit 40 and the second locking unit 6) or the charging module 3 can be used in conjunction with the operation module 4, the first locking module 5 and the second locking unit 6.
[0105] Please see Figure 17 The figure shows a perspective view of an embodiment of the accessory kit for the physiological parameter monitoring device according to the present invention, filled with health management equipment. As shown, the accessory kit 500 for the physiological parameter monitoring device includes a closable body 510 suitable for accommodating multiple health monitoring devices, such as a transmitter container 520 for accommodating a transmitter (not shown), a charger 540 for charging the transmitter, and a splitter 560 for separating the used physiological parameter monitoring device from the transmitter.
[0106] The closable body 510 includes a first blade 512, a second blade 514, and an end portion 516 connecting the first blade 512 and the second blade 514. Furthermore, the first blade 512 and the second blade 514 are foldable around the end portion 516, thus these three components together form a container for accommodating multiple physiological monitoring device accessories. A button 515 is provided on the second blade 514 and configured to engage with a locking portion 513 to unlock or close the latched closable body 510. In some embodiments, at least one of the first blade 512 and the second blade 514 is a housing formed of a plastic material. In other embodiments, the housing may be formed of fabric, leather, wood, paper, or metal, or a combination thereof.
[0107] The accessory kit 500 for the physiological parameter monitoring device includes a closable body 510 suitable for storing multiple accessories for the physiological parameter monitoring device, such as a transmitter container 520 for accommodating a transmitter (not shown), a charger 540 for charging the transmitter, and a splitter 560 for separating the used physiological parameter monitoring device from the transmitter.
[0108] The accessory kit 500 for the physiological parameter monitoring device includes a housing made of plastic, a recyclable and environmentally friendly material. This allows users to recycle and reuse the device at the end of its lifespan through appropriate recycling processes, thereby reducing environmental pollution. Furthermore, the plastic housing is designed to be robust, durable, and reusable, providing long-term stable use.
[0109] This utility model's storage box not only meets users' needs for convenient storage of health management products, but also aligns with the requirements of sustainable development and environmental protection in modern society, realizing the core principles of ESG (Environmental, Social, and Governance). This design not only enhances the product's economic benefits but also has a positive impact on society and the environment.
[0110] Please see Figure 18 The illustration shows a perspective view of an embodiment of the accessory kit 500 for the physiological parameter monitoring device of this invention, without any accessories installed therein. The first blade 512 has multiple compartments 5121, 5122, and 5123, each suitable for accommodating multiple accessories. (See comparison) Figure 17 and Figure 18 These compartments 5121, 5122, and 5123 can respectively accommodate a charger 540, a transmitter container 520, a splitter 560, or a cable 580. In other embodiments, compartments 5121, 5122, and 5123 can be configured to accommodate different components for accessory kits.
[0111] The housing of the first blade 512 has a first edge 512A, and the housing of the second blade 514 has a second edge 514A. When the body 510 is in the closed state, the first edge 512A and the second edge 514A match each other. The end 516 includes a pivot assembly 516A to allow the first and second blades 512, 514 to rotate around the end 516 to fold into one piece or separate.
[0112] exist Figure 18 In this embodiment, the first blade 512 includes a first lining 512B disposed within a housing of the first blade 512 and forming compartments 5121, 5122, 5123 therein. In one embodiment, the first lining 512B is formed of a first lining material different from a plastic material, such as wood, paper, or metal. In other words, the first blade 512 may be formed of a different material than the second blade 514. The compartments are configured to accommodate a corresponding portion of one of a plurality of health monitoring devices.
[0113] exist Figure 18In this embodiment, the first blade 512 includes a first lining 512B disposed within the housing of the first blade 512 and forming compartments 5121, 5122, 5123 therein. In one embodiment, the first lining 512B is formed of a first lining material different from plastic material, such as wood, paper, or metal. In other words, the first blade 512 may be formed of a different material than the second blade 514. The second blade 514 includes a second lining 514B disposed within the housing of the second blade 514, having at least one auxiliary compartment configured to accommodate a corresponding portion of one of the plurality of health monitoring devices. According to one viewpoint, the first blade 512 can be considered as a first housing, and the second blade 514 can be considered as a second housing.
[0114] Compared to some methods that use paper materials to package and transport accessories such as charger 540, transmitter container 520, and splitter 560, this invention uses a plastic accessory kit 500 instead of paper packaging materials to reduce the risk of product damage during packaging and transportation. The plastic container provides better protection and effectively absorbs external impacts, thereby reducing the risk of product damage during transportation.
[0115] This improved design is suitable for a variety of products requiring transportation, especially fragile or valuable items. The cushioned container, made from recyclable plastic, not only enhances product safety but also meets environmental and sustainability requirements. This design effectively reduces losses and waste caused by transportation damage, improves user experience and satisfaction, and significantly enhances supply chain management and logistics efficiency.
[0116] Figure 19 The transmitter container 520 shown has a diameter of approximately 33.2 mm and a height of 32.5 mm, and includes a container body 521 and a lid 523 for accommodating two transmitters 522. When one transmitter 522 is in use, the other can serve as a backup. Additionally, the transmitter container 520 may optionally contain a replaceable desiccant 525 to keep the transmitters 522 dry, prevent moisture damage, and extend their lifespan.
[0117] Figures 20A-20C The concept of using a splitter 560 to separate the transmitter 522 and the used sensor module 8 is illustrated. The user removes the two parts, which are joined together, from the body surface and places them into the splitter 560. The cover 562 is then closed, allowing the splitter 560 to easily separate the reusable transmitter 522 from the sensor module 8.
[0118] like Figure 20D-20EAs shown, the physiological parameter monitoring device 1 includes a base 80, a sensor assembly 81, and a transmitter 7. The base 80 includes a base body 801 and at least one first snap-fit structure 83. The base body 801 has a base plate 802 for mounting on the skin surface S of a living organism. The first snap-fit structure 83 is disposed on the top surface of the base plate 802. The sensor assembly 81, including a sensor 810, can be disposed on the base 80 and is suitable for measuring at least one analyte in the living organism and transmitting corresponding physiological signals. The transmitter 7 is detachably mounted on the base body 802 and connected to the sensor 810, and is used to receive and output physiological signals. The transmitter 7 includes a bottom shell 75 and at least one second snap-fit structure 72. The bottom shell 75 faces the top surface of the base plate 802 of the base body 801. The second latching structure 72 is disposed on the bottom shell 75 corresponding to the first latching structure 83 of the base 80. When the transmitter 7 covers the base body 801 with the bottom shell 75 facing the top surface of the base plate 801, the second latching structure 72 engages with the first latching structure 83.
[0119] In this embodiment, the base body 801 has at least one opening 803 for the user to apply external force to separate the second latching structure 72 from the first latching structure 83, thereby allowing the transmitter 7 to separate from the base body 801. This external force can be applied using a splitter 560.
[0120] like Figure 20F The image shown is a three-dimensional structural diagram of the splitter 560. Figure 20G It is along Figure 20EA cross-sectional view along centerline IX-IX shows a splitter 560, which includes at least: a base 5610 having a first receiving groove 5610A and a second receiving groove 5610B that are interconnected; a top cover 5611 pivotally mounted on one side of the base 5610 to open and close relative to the base 5610, and the top cover having a button 5612 and a drive assembly 5613 and a pusher 5614 connected to the button 5612; wherein, when the top cover 5611 is opened relative to the base 5611, the physiological parameter monitoring device 1 can be received in the first receiving groove 5610A with the transmitter 7 side facing downward; when the top cover 5611 is in the closed state, the pusher 5614 can be driven to pass through the opening 803 of the base 5610 in a first direction to push against the transmitter 7, thereby separating the transmitter 7 from the sensor module 8. In another embodiment, button 5612 can be replaced by a soft part (not shown). Operating the soft part activates the pusher 5614, which moves along the first direction through the opening 803 to push the transmitter 7, thus separating the transmitter from the sensor module 8 and allowing it to leave the first receiving groove 5611A. The base 5610 has a second receiving groove 5610B that communicates with the first receiving groove 5610A, allowing the transmitter 7 to enter the second receiving groove 5610B when separated from the sensor module 8. The splitter 560 provides a user with an effective and easy way to separate the physiological monitoring device 1 from the sensing base 80 of the sensor module 8.
[0121] All components, including the charger 540, transmitter container 520, splitter 560, and other accessories, can be stored in the accessory kit 500 for the physiological parameter monitoring device when not in use. The sturdy container provides users with a convenient and safe way to store and reuse the device in daily life.
[0122] Figure 21 This invention illustrates another embodiment of the present invention, without a charging device 2 mounted on the transmitter. The charging device 2 includes an upper window 10a3 on a cover plate 10a1 and a slider 10a4. After the transmitter (not shown) is placed on the placement part 13 and charging is complete, the transmitter can be removed from the placement part 13 using the slider 10a4, making it convenient for the user to remove the transmitter. In one embodiment, if a larger transmitter is used, the slider 10a4 can be omitted because the exposed area of the transmitter is larger, making it easier to disassemble.
[0123] Please refer to Figures 21A-21C for schematic diagrams of the operation steps for charging the transmitter using the charger. When the power cable 580 (not shown) is inserted into the socket (not shown), the operating element 94 is pushed towards the charging indicator light 96, causing the charging indicator light 96 to extend outward. Figures 21A-21CIn this process, the locking module 10a5 is unlocked, thus allowing the first conductive connector 95 to move upwards. During this process, as the cable 580 continues to be inserted into the charging device 2, the first locking module 10a5 is pushed upwards by the operating member 94, providing power charging. In one embodiment, a light source 961 is provided on the outside of the charging indicator 96, which illuminates when there is charging current in the first conductive connector 95.
[0124] Please refer to Figure 17-21 The invention discloses a method of operating an accessory kit 500 for a physiological parameter monitoring device, comprising the following steps: (a) opening the first leaf of the accessory kit 500; (b) removing the transmitter container 520 from the accessory kit 500; (c) removing the transmitter 522 from the transmitter container; (d) placing the transmitter 522 onto the sensor module 8 to form a physiological parameter monitoring device; (e) (f) After measurement, the splitter 560 is removed from the accessory kit 500 for the physiological parameter monitoring device; (g) The physiological parameter monitoring device is placed inside the splitter 560 to separate the transmitter 522 from the used sensor module 8; (h) The transmitter 522 is placed on the placement section 13 of the charger 540 and charging of the transmitter 522 begins; (i) After charging is complete, the transmitter 522 is removed from the charger 540; and (j) The charged transmitter 522 is stored in the transmitter container 520. The placement section 13 is configured to allow the transmitter 522 on it to be charged, and the splitter 560 is configured to separate the transmitter 522 from the used sensor module 8 to allow the transmitter 522 to be charged via the charger 540.
[0125] Please see Figures 22A-22D This illustrates other different embodiments of the present invention. The accessory kit for the physiological parameter monitoring device proposed in this invention can be designed to carry different equipment, among which... Figure 22A The accessory kit 600 for the physiological parameter monitoring device shown is configured to house a charger 540 for charging the transmitter and a splitter 560 for separating the used physiological parameter monitoring device from the transmitter. In the first operating state, when the closable body 510 is in the open state, the splitter 560 is removed, the physiological parameter monitoring device 1 is placed in the splitter 560, and the sensor base 80 is separated from the transmitter 7 by operating the splitter 560. In the second operating state, the charger 540 is removed, and the transmitter 7 is placed in the slot 13 of the charger 540 to connect to an external power source for charging.
[0126] Figure 22BThe accessory kit 700 for the physiological parameter monitoring device shown is configured to house a transmitter container 520 for accommodating a transmitter (not shown) and a splitter 560 for separating the used physiological parameter monitoring device from the transmitter. In a first operating state, when the closable body 510 is in the open state, the transmitter 7 is removed from the transmitter container 520 and installed into the sensor module 8 to form the physiological parameter monitoring device 1 for physiological parameter monitoring; in a second operating state, the transmitter 7 is placed in the charger for charging.
[0127] Figure 22C The accessory kit 800 for the physiological parameter monitoring device shown is configured to house a transmitter container 520 for accommodating a transmitter (not shown) and a charger 540 for charging the transmitter. In a first operating state, when the closable body 510 is in the open state, the transmitter 7 is removed from the transmitter container 520 and installed into the sensor module 8 to form the physiological parameter monitoring device 1 for monitoring physiological parameters; in a second operating state, the transmitter 7 is placed in the charger for charging.
[0128] Figure 22D The accessory kit 900 for the physiological parameter monitoring device shown is configured to house a transmitter container 520 for accommodating a transmitter (not shown), a charger 540 for charging the transmitter, and a splitter 560 for separating the used physiological parameter monitoring device from the transmitter. In a first operating state, when the closable body 510 is open, the transmitter 7 is removed from the transmitter container 520 and installed onto the sensor module 8 to form the physiological parameter monitoring device 1 for physiological parameter monitoring. In a second operating state, the splitter 560 is removed to separate the used physiological parameter monitoring device 1 from the sensor base 80 and the transmitter 7.
[0129] Needs explanation Figure 22D The locking portion 913 of the accessory kit 900 for the physiological parameter monitoring device shown is different from the locking portion 513 of the accessory kit 500 for the physiological parameter monitoring device; the locking directions of the two are opposite. Those skilled in the art can configure different types of locking assemblies, all of which do not exceed the scope of this invention.
[0130] Although the present invention has been described according to embodiments currently considered to be the most practical and preferred, it should be understood that the present invention is not necessarily limited to the disclosed embodiments. Rather, it is intended to cover various modifications and similar arrangements included within the spirit and scope of the appended claims, consistent with the broadest interpretation, thereby encompassing all such modifications and similar structures.
[0131] [Explanation of Labels in the Attached Image]
[0132] 1: Charging device
[0133] 10: Shell, Body
[0134] 10a: Upper shell
[0135] 10a1: Cover plate
[0136] 10a3: Upper window
[0137] 10a4: Slider
[0138] 10a5: Locking Module
[0139] 10b: Lower housing
[0140] 10b1: Guiding component
[0141] 10b2: Pivot Frame
[0142] 101: Upper limiting rib
[0143] 102: Lateral restraint rib
[0144] 103a: First positioning groove
[0145] 103b: Second positioning groove
[0146] 11: Indicator Area
[0147] 12: Push / Pull Buttons
[0148] 120: Positioning Block
[0149] 13: Placement Section
[0150] 14: First Coordination Department
[0151] 15: Opening, Opening
[0152] 150: Guiding section
[0153] 150': Slide
[0154] 16: Baffle outlet
[0155] 17: Opening
[0156] 2: Storage device
[0157] 20: Shell
[0158] 20': First accommodating space
[0159] 21: Second Accommodation Space
[0160] 22: Flexible components
[0161] 23: First buckle edge
[0162] 23': Opening
[0163] 24: Cover
[0164] 25: Second buckle edge
[0165] 27: The part being pushed
[0166] 28: Hole Structure
[0167] 29: Desiccant
[0168] 3: Charging module, lifting unit
[0169] 30: Charging dock
[0170] 301: First slider, second guide structure
[0171] 302: Second slider, slider seat
[0172] 31: First conductive connector, gold fingers
[0173] 32: Second conductive connector
[0174] 33: Circuit components
[0175] 330: Circuit board
[0176] 331: Flexible electrical connector
[0177] 332: Light-emitting components
[0178] 4: Operation Module
[0179] 40: Operations Department
[0180] 41: First Guiding Structure
[0181] 41a: First transverse groove
[0182] 41b: Second transverse groove
[0183] 42: Second connecting end
[0184] 43: Blocked part
[0185] 44: Electrical connector plug (third electrical port)
[0186] 45: Power Supply Department
[0187] 46: Rechargeable battery
[0188] 47: Power supply circuit board
[0189] 5: Stop module
[0190] 50: Pivot section
[0191] 51: Actuator
[0192] 52: Stop end
[0193] 52': Light guide
[0194] 53: Flexible components
[0195] 500 / 600 / 700 / 800 / 900: Accessory kits for physiological parameter monitoring devices
[0196] 510: Closeable body
[0197] 512: First blade
[0198] 512A: First Edge
[0199] 5121 / 5122 / 5123: Compartments
[0200] 513 / 913: Locked section
[0201] 514: Second blade
[0202] 514A: Second Edge
[0203] 515: Button
[0204] 516: End
[0205] 516A: Pivot Assembly
[0206] 520: Launcher Container
[0207] 521: Container body
[0208] 522: Launcher
[0209] 523: Lid
[0210] 540: Charger
[0211] 560: Splitter
[0212] 5610: Base
[0213] 5610A: First receiving slot 5610A
[0214] 5610B: Second receiving slot 5610B
[0215] 5611: Top Cover
[0216] 5612: Button
[0217] 5613: Driver component
[0218] 5614: Push-pull component
[0219] 562: Cover plate
[0220] 580: Cable
[0221] 6: Positioning mechanism
[0222] 6': Connector
[0223] 60: First connecting end
[0224] 61: Baffle
[0225] 62: Flexible components
[0226] 63: Guiding Structure
[0227] 7: Transmitter
[0228] 70: Second Coordination Unit
[0229] 71: Battery
[0230] 72: First snap-fit structure
[0231] 73: Input Section
[0232] 730: Input Terminal
[0233] 731: Secondary conductive terminal
[0234] 74: Sensing Module
[0235] 8: Sensor Module
[0236] 80: Sensor base
[0237] 801: Base Body
[0238] 802: Base Plate
[0239] 803: Opening
[0240] 81: Sensor Components 810: Sensor (Analyte Sensor)
[0241] 811: Puncture end
[0242] 812: Output terminal
[0243] 82: Sensor assembly fixing structure
[0244] 83: Second snap-fit structure
[0245] 84: Matching Alignment Part
[0246] 9: External power supply
[0247] 91: Personal Computer
[0248] 92: Mobile phone charger
[0249] 93: Car cigarette light USB adapter
[0250] S: Skin
[0251] SC: Subcutaneous tissue
[0252] ST: Adhesive patch.
Claims
1. An accessory kit for a physiological parameter monitoring device, the physiological parameter monitoring device including a sensing base, a sensor disposed on the sensing base, and a transmitter detachably covered on the sensing base, wherein the sensing base has at least one opening, and the accessory kit comprising: The closable body is used to store multiple accessories used in this physiological parameter monitoring device, including: The closable body has multiple compartments for accommodating the multiple accessories, which include at least a transmitter container for storing the transmitter and a splitter for separating the used physiological parameter monitoring device from the transmitter, wherein the used physiological parameter monitoring device includes an analyte sensor. In the first operating state, when the closable body is in the open state, the transmitter is taken out from the transmitter container and installed on the sensor to form the physiological parameter monitoring device for monitoring physiological parameters; in the second operating state, the splitter is taken out to separate the used sensor base from the transmitter.
2. The sleeve as claimed in claim 1, wherein the closable body comprises a first housing and a second housing, which cooperate to switch between a closed state and an open state.
3. The set as claimed in claim 2, wherein the first housing further includes a first lining disposed inside the housing and forming the plurality of compartments therein, the first lining being formed of a first lining material, and the first lining material being different from plastic.
4. The sleeve as claimed in claim 2, wherein the first housing has a first outer edge, the second housing has a second outer edge, and the first outer edge and the second outer edge engage when the closable body is in a closed state.
5. The kit of claim 2, further comprising a hinge portion connecting the first housing and the second housing, wherein the first housing and the second housing are configured to be foldable around the hinge portion.
6. The assembly as claimed in claim 2, wherein the second housing further includes a second lining disposed inside the housing of the second housing, the second lining having at least one corresponding compartment configured to accommodate at least one of the plurality of accessories in a corresponding portion that is not fully accommodated within the first housing.
7. The kit as claimed in claim 1, further comprising an outer bag for surrounding and packaging the accessory kit for the physiological parameter monitoring device to facilitate portability.
8. An accessory kit for a physiological parameter monitoring device, the physiological parameter monitoring device including a sensing base, a sensor disposed on the sensing base, and a transmitter detachably covered on the sensing base, wherein the sensing base has at least one opening, and the accessory kit includes: The closable body is used to store multiple accessories used in this physiological parameter monitoring device, including: The closable body has multiple compartments for accommodating the multiple accessories, including at least a transmitter container for storing the transmitter and a charger for charging the transmitter.
9. The kit of claim 8, wherein the charger has a top cover and includes a top window and a slider located on the top cover for facilitating the user to remove the transmitter after charging.
10. An accessory kit for a physiological parameter monitoring device, the physiological parameter monitoring device including a sensing base, a sensor disposed on the sensing base, and a transmitter detachably covered on the sensing base, wherein the sensing base has at least one opening, the accessory kit comprising: The closable body is used to store multiple accessories used in this physiological parameter monitoring device, including: The closable body has multiple compartments for accommodating the multiple accessories, including at least a charger for charging the transmitter and a splitter for separating the used physiological parameter monitoring device from the transmitter, wherein the used physiological parameter monitoring device includes an analyte sensor.