A separate assembly for an ocular ion pulse therapy device

Abstract

The utility model discloses a separation type assembly for eye ion pulse treatment device, it includes first submodule and second submodule, first submodule, second submodule all have strip shape shell part, the strip shape shell of first submodule is built -in with power part, the strip shape shell of second submodule is built -in with control part, and first submodule, second submodule between be provided with the second flexible wire harness of realizing each other's mutual electric property connection, and first submodule end, second submodule end part are provided with respectively with the first flexible wire harness of electric property connection of the ground end conductor element, high voltage end conductor element of eye ion pulse treatment device set. This separation type assembly integrates power part, control module in the assembly, and the self -weight of the glasses matched with it is effectively reduced, and installation and maintenance are all more convenient.

Description

Technical Field

[0001] This utility model relates to a detachable component for an eye ion pulse therapy device. Background Technology

[0002] Utility model patent CN107982636A discloses an eye ion pulse therapy device, comprising: a carrier for mounting conductive elements on the acupoint area of ​​the eye; a power supply disposed on the carrier and electrically connected to a control board; a high-voltage generating element disposed on the carrier and electrically connected to the control board; two conductive elements mounted on the carrier and used for treatment, the two conductive elements being in contact with the surface skin of the acupoint area of ​​the eye; one of the two conductive elements being electrically connected to the grounding terminal of the high-voltage generating element, and the other conductive element being electrically connected to the high-voltage terminal of the high-voltage generating element. The negative ions (electrons) of this eye ion pulse therapy device, after entering the acupoint area of ​​the eye, promote microcirculation in the eye area, thereby accelerating cell metabolism, effectively relieving eye fatigue, and promoting eye health. While effectively relieving eye fatigue, this product is also suitable for general use; however, for teenagers, the lightweight design of the eye ion pulse therapy device is more advantageous for their use. Utility Model Content

[0003] The present invention aims to solve the above-mentioned technical problems and provide a highly integrated and modularly designed detachable component for an eye ion pulse therapy device. It is detachably installed in the eye ion pulse therapy device, making the glasses lighter and easier to replace as a whole, saving the trouble of disassembling and repairing the glasses.

[0004] To solve the above-mentioned technical problems, the present invention provides a detachable component for an ocular ion pulse therapy device, which includes a first submodule and a second submodule. Both the first submodule and the second submodule have an elongated outer shell. The elongated outer shell of the first submodule houses a power supply, and the elongated outer shell of the second submodule houses a control unit. A second flexible wire harness is provided between the first submodule and the second submodule to achieve mutual electrical connection. The ends of the first submodule and the second submodule are respectively provided with a first flexible wire harness that is electrically connected to the grounding conductor element and the high-voltage conductor element of the ocular ion pulse therapy device.

[0005] As can be seen from the above, this separate component integrates the power supply and control module into the component, effectively reducing the weight of the matching glasses and making installation and maintenance more convenient.

[0006] Furthermore, the elongated outer shell has an elongated top shell with one end being semi-circular. A first side shell and a second side shell are distributed on both sides of the top shell. A bottom shell is provided at the bottom of the first side shell and the second side shell. The shell formed by the top shell, side shell, second side shell and bottom shell has a front shell at one end and a conical rear shell at the other end. The conical rear shell has a wire harness passage hole.

[0007] Furthermore, the elongated outer shell of the first submodule is equipped with control buttons.

[0008] Furthermore, the elongated outer shell of the first submodule is equipped with a display device, which is connected to the control unit.

[0009] Furthermore, the end of the first flexible wire harness is provided with a socket structure.

[0010] Furthermore, the first submodule and the second submodule, the first flexible wire harness, and the second flexible wire harness are integrated into a single module. Attached Figure Description

[0011] Figure 1 This is a perspective view of a separate component of an ocular ion pulse therapy device according to the first embodiment of this utility model.

[0012] Figure 2 This is a three-dimensional representation of the first sub-module in the split-type assembly of the ocular ion pulse therapy device according to the first embodiment of this utility model. Figure 1 .

[0013] Figure 3 This is a three-dimensional representation of the first sub-module in the split-type assembly of the ocular ion pulse therapy device according to the first embodiment of this utility model. Figure 2 .

[0014] Figure 4 This is a three-dimensional representation of the first sub-module in the split-type assembly of the ocular ion pulse therapy device according to the first embodiment of this utility model. Figure 3 .

[0015] Figure 5 This is a perspective view of the second sub-module in the split-type component of the ocular ion pulse therapy device according to the second embodiment of this utility model.

[0016] Figure 6 This is a perspective view of the ocular ion pulse therapy device in the second embodiment of this utility model.

[0017] Figure 7 This is a partial structural diagram of the high-voltage harness bending mechanism in the second embodiment of the present invention.

[0018] Figure 8 This is a partial structural diagram of the inner extension body of the lower deflection section in the second embodiment of this utility model.

[0019] Figure 9 This is a partial structural diagram of the safety high-voltage interface in the second embodiment of this utility model.

[0020] Figure 10 This is an exploded view of the ocular ion pulse therapy device in the third embodiment of this utility model. The independent control terminal is omitted in this view. Detailed Implementation

[0021] To make the technical means, creative features, objectives and effects of this utility model easier to understand, the present utility model will be further described below in conjunction with specific embodiments.

[0022] The first embodiment of this utility model provides a detachable component for an eye ion pulse therapy device. This detachable component can be used as a standard accessory to adapt to the eye ion pulse therapy device. Two corresponding electrodes are installed at the nose pad of the eye ion pulse therapy device, and an external interface is provided at the free end of the temple of the glasses to adapt to this utility model. The following is a detailed description with reference to the accompanying drawings.

[0023] See Figure 1-5 As shown, the detachable component of the eye ion pulse therapy device includes a first submodule 30 and a second submodule 31. Both modules can be hung around the neck. Both the first submodule 30 and the second submodule 31 have elongated outer shell sections 32. The elongated design facilitates hand grip and allows for a natural drooping effect. The elongated shell of the first submodule houses a power supply section, which is a rechargeable battery for easy recharging when the battery is depleted. The elongated shell of the second submodule houses a control section. The PCB circuit board of the control section integrates a control board, a high-voltage board, etc. A second flexible wiring harness 5 is provided between the first and second submodules to electrically connect them, allowing the first submodule to supply power to the second submodule. The ends of the first and second submodules are respectively provided with first flexible wiring harnesses 4, which are electrically connected to the grounding conductor and the high-voltage conductor of the eye ion pulse therapy device. The first flexible wiring harnesses 4 can connect to the corresponding interfaces on the temples of eyeglasses to electrically connect the two electrodes at the nose pad.

[0024] This detachable component integrates the power supply and control module into one unit, distributing the overall weight between the two sub-modules. By distributing the weight across the neck, it effectively reduces the weight of the matching glasses, making it possible for consumers to wear them for extended periods. The plug-in structure at the end facilitates electrical connection with the temple ports of the glasses, and the entire component can be replaced if it is damaged.

[0025] See Figure 2-5As shown, the elongated outer shell can be made of plastic and has an elongated top shell 32a with one end semi-circular. A first side shell 32b and a second side shell 32c are distributed on both sides of the top shell. A bottom shell 32d is located at the bottom of the first side shells 32b and the second side shells 32c. The shell formed by the top shell, side shells 32b, second side shells 32c, and bottom shell 32d has a front shell 32e at one end and a conical rear shell 32f at the other end. The conical rear shell has a wire harness passage hole. The structures of the elongated outer shells of the two sub-modules are largely the same. The elongated outer shell of the first sub-module has a control button, which can be used to start or stop the ion pulse therapy device. To facilitate the display of relevant parameters, the elongated outer shell of the first sub-module has a display device connected to the control unit. The display device displays parameters including, but not limited to, battery level.

[0026] In this detachable assembly, the socket structure at the end of the first flexible wire harness can be a male connector, while the corresponding end of the eyeglasses is provided with a female connector, and vice versa. This allows for quick assembly and disassembly.

[0027] In this embodiment, the first sub-module 30 and the second sub-module 31, the first flexible wire harness and the second flexible wire harness are an integrated module. The integrated module provides product integration while facilitating the needs of commercial deployment.

[0028] The second embodiment of this utility model provides an ocular ion pulse therapy device, which is adapted to the detachable component for an ocular ion pulse therapy device provided in the first embodiment. See [link to first embodiment]. Figure 5-9 It includes an eyeglass end 1, a nose pad 2, an independent control end 3, a first flexible wire harness 4, and a second flexible wire harness 5. Compared with traditional products, the inventors have optimized the structure of the eye ion pulse therapy device, which not only meets the need for lightweight eyeglasses but also facilitates the adaptation of the structure to the characteristics of groups such as teenagers.

[0029] exist Figure 5 As can be seen from the diagram, the eyeglass end 1 can refer to the eyeglass structure in the prior art, that is, it has parts such as the frame. Conductive elements are provided at the two nose pads 2 at the eyeglass end. The nose pads can be made of conductive / semiconductor materials. The nose pads made of conductive / semiconductor materials are connected to the corresponding lines in the frame and temples, thereby realizing electrical connection with the grounding terminal and high voltage terminal of the high voltage generating element. Considering that the eyeglass frame is decomposed into a frame and frame cover in this invention, conductive inserts can be injection molded into the frame, with 2 conductive pins exposed for fixing the nose pads. When the nose pads are made of semiconductor material, the functional requirements can be met.

[0030] It is worth mentioning that in this embodiment, the glasses end is detachably connected to an independent control end 3 via a first flexible wire harness 4. The first flexible wire harness 4 serves both as a lanyard and as a power cord internally. The sheath of the first flexible wire harness can be a rubber sheath, which is soft, durable, and provides insulation and protection for the power lines. The independent control end has two sub-modules, which can be block-shaped, such as a shell structure encapsulated in a plastic shell. Corresponding supporting structures are built into the shell structure. The two sub-modules are defined as the first sub-module 30 and the second sub-module 31, respectively. The first sub-module 30 houses the power supply section to power the eye ion pulse therapy device. The power supply section is a rechargeable battery. The second sub-module 31 houses the control section. The shell structure of the second sub-module can be equipped with a display screen to display the corresponding parameters. If permissible, the display screen can be selected as a touch screen, in which case the entire device is displayed via the touch screen. Of course, a traditional display screen combined with the mechanical control buttons set in the second sub-module is also permissible. A second flexible wire harness 5 is provided between the two sub-modules. The second flexible wire harness also adopts a rubber sheath structure, with corresponding wiring laid out internally.

[0031] In this embodiment, the control part installed inside the second submodule has a high-voltage generating element. The high-voltage generating element is connected to the control board, and the control board is electrically connected to the power supply part. Two conductor elements are respectively connected to the grounding terminal and the high-voltage terminal of the high-voltage generating element.

[0032] During use, users can directly control the entire eye ion pulse therapy device through the second sub-module. The two sub-modules effectively reduce the weight of the power supply and PCB circuit board (with built-in high-voltage circuit board, control board, etc.) in the eye ion pulse therapy device. The weight of the frame is no different from that of traditional glasses, which greatly alleviates the discomfort caused to users when the frame weight exceeds that of traditional glasses, and provides the possibility for the large-scale commercialization of eye ion pulse therapy devices.

[0033] The eye ion pulse therapy device provided by this utility model is designed with a glasses end and an independent control end. The two ends are separate from each other and are organically connected together by a flexible wire harness. This not only meets the need for lightweight glasses, but also allows the eye ion pulse therapy device to be hung around the neck for easier use. It is also suitable for teenagers and is equipped with corresponding fatigue relief functions.

[0034] See Figure 6Although the eyeglass end 1 can be rotatably connected to the adjacent positions of the frame 10 and temple 11 via hinges, the frame and temple of the eyeglass end require the installation of corresponding wiring harnesses (power cords, etc.). Repeated bending can easily cause fatigue and breakage of the metal wiring. Here, a high-voltage wiring harness bending mechanism 6 can be arranged at the adjacent positions of the frame and temple. This high-voltage wiring harness bending mechanism is made of rubber. The main body of the high-voltage wiring harness bending mechanism has several protrusions distributed along the length direction and gaps distributed between the protrusions on its side. The two ends of the main body are connected to the temple and the folded edge of the frame.

[0035] See Figure 7 The temple of the eyeglasses has an integrally formed downward-angled inner extension 7 at an obtuse angle to the temple. This downward-angled inner extension 7 serves two purposes: firstly, it conforms to the area behind the ear, preventing the high-voltage interface from being near the space between the ear and brain, thus avoiding safety risks; secondly, the figure-eight-shaped extensions can be used to close the temple and ensure a tight fit against the inside of the ear and brain, preventing the frame from tilting up due to the independently controlled end. (See [link]). Figure 9 The inner extension body of the lower deflection type is provided with a glasses end terminal 8, and the flexible wire harness of the independent control end is provided with a control end terminal 9 that cooperates with the glasses end terminal. Matching terminals are provided on the glasses end terminal 9 and the control end terminal 9, for example, one male terminal is matched with one female terminal. After the terminals are connected, the high voltage end and grounding end of the control end can be electrically connected to the grounding end conductor element and the high voltage end conductor element at the nose pad.

[0036] As an alternative, a strip 12 is detachably installed on the outer side of one temple near the inner extension of the lower deflection section. This strip can serve as an auxiliary structure to wrap around the head to improve the stability of the product during special scenarios such as sports. It is a detachable component. The other temple is provided with a strip fixing part near the inner extension of the lower deflection section. In this embodiment, cylindrical protrusion fixing parts are arranged at equal intervals on the outer side of the temple, and the strip is provided with multiple round holes that cooperate with the cylindrical protrusion fixing parts. Through the above structure, the strip can be adjusted and assembled to adjust the effective length of the strip.

[0037] The third embodiment of this utility model provides an ocular ion pulse therapy device, see [link to relevant documentation]. Figure 10 It includes an eyeglass end 1, which includes a frame 10 and temples 11. The frame can be fitted with lenses 14. The frame 10 has frame cover plates 10a, and the temples have temple cover plates 11a. A conductive insert 13 is injection molded into the frame, with two conductive pins exposed for fixing the nose pads 2.

[0038] In this embodiment, the nose pad is made of semiconductor material. The frame cover has pivot holes at both ends, and the temples have hollow pivots at corresponding positions. The pivots are inserted into the pivot holes, allowing the high-voltage wire 15 to pass through the center of the pivot and enter the frame. A temple fixing plate is located above the temple to secure it to the pivot position. This allows the temples to rotate and the passage of the thick high-voltage wire. Both the temples and the temple cover are made using two-color injection molding. Anti-slip rubber extends from the outer layer of the ear area to the tail of the temple. A connecting terminal is located at the tail of the temple, with a metal pin in the center and protected by rubber.

[0039] The electrical components feature a separate, independent control design. In this embodiment, a lanyard is used for wearing around the neck. The first sub-module, serving as the independent control unit, functions as the power supply, while the second sub-module functions as the control unit. The battery and control units are connected by a non-slip rubber cord. The inner extension of the temple's downward deflection section has a lens end terminal. The flexible wiring harness of the independent control unit has control end terminals that mate with the lens end terminals. Specifically, both the battery and control units have connection terminals at their outer ends, each with a hole in the center corresponding to the temple terminal as a lens end terminal. Both terminals are designed for a tight fit, ensuring a secure hold.

[0040] Those skilled in the art will understand that the above embodiments are specific examples of implementing the present invention, and in practical applications, various changes can be made to them in form and detail without departing from the spirit and scope of the present invention.

Claims

1. A separate component for an ocular ion pulse therapy device, characterized in that, It includes a first submodule and a second submodule. Both the first submodule and the second submodule have a long strip-shaped outer shell. The long strip-shaped outer shell of the first submodule houses the power supply section, and the long strip-shaped outer shell of the second submodule houses the control section. A second flexible wire harness is provided between the first submodule and the second submodule to achieve mutual electrical connection. The ends of the first submodule and the second submodule are respectively provided with a first flexible wire harness that is electrically connected to the grounding end conductor element and the high-voltage end conductor element of the eye ion pulse therapy device.

2. The split-type component for an ocular ion pulse therapy device according to claim 1, characterized in that, The elongated outer shell has an elongated top shell with one end being semi-circular. A first side shell and a second side shell are distributed on both sides of the top shell. A bottom shell is provided at the bottom of the first side shell and the second side shell. The shell formed by the top shell, side shell, second side shell and bottom shell has a front shell at one end and a conical rear shell at the other end. The conical rear shell is provided with a wire harness passage hole.

3. The split-type component for an ocular ion pulse therapy device according to claim 1, characterized in that, The elongated outer shell of the first submodule is equipped with control buttons.

4. The split-type component for an ocular ion pulse therapy device according to claim 1, characterized in that, The elongated outer shell of the first submodule is equipped with a display device, which is connected to the control unit.

5. The detachable component for an ocular ion pulse therapy device according to claim 1, characterized in that, The first flexible wire harness has a socket structure at its end.

6. The detachable component for an ocular ion pulse therapy device according to any one of claims 1-5, characterized in that, The first submodule, the second submodule, the first flexible wire harness, and the second flexible wire harness form an integrated module.

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