Wearable body temperature detection device
By integrating an infrared temperature sensor, an adaptive wearing component, and a micro servo motor to drive the fever-reducing patch into a wearable body temperature detection device, the problem of timely emergency treatment when children suddenly develop a high fever is solved, achieving both accuracy and safety in body temperature monitoring.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- SINOPHARM CHONGQING PHARMA & MEDICAL IND DESIGN INST
- Filing Date
- 2023-06-21
- Publication Date
- 2026-07-07
AI Technical Summary
Existing wearable temperature detection devices cannot provide timely emergency response when children suddenly develop a high fever, resulting in inaccurate temperature monitoring and the potential for harm to children's health.
A wearable body temperature detection device was designed, comprising an infrared temperature sensor, a control terminal, a power supply component, an adaptive wearing component, and a fitting mechanism. It utilizes a micro servo motor to drive a cooling patch to be attached to the forehead for emergency cooling. Combined with a delay module and an alarm device, it ensures timely handling of body temperature fluctuations.
It enables real-time monitoring of children's body temperature and emergency cooling measures, reducing misjudgments caused by temperature fluctuations and ensuring children's safety.
Smart Images

Figure CN116839735B_ABST
Abstract
Description
Technical Field
[0001] This invention belongs to the field of wearable body temperature detection technology, and specifically relates to a wearable body temperature detection device. Background Technology
[0002] Children have weaker immune systems during their growth, making their respiratory tracts more susceptible to viral or bacterial infections, leading to viral colds or pneumonia. When children have viral colds or pneumonia, they are prone to sudden high fevers. If guardians or medical personnel fail to detect and treat this promptly, it can easily harm the child's health. Existing temperature monitoring devices can monitor and alert children's temperatures in real time; however, children are often active, and sometimes emotional excitement can cause a sudden rise in temperature, resulting in inaccurate temperature monitoring alerts. Furthermore, existing wearable temperature monitoring devices cannot provide emergency cooling for wearers with sudden high fevers; treatment must wait for medical personnel to arrive. Sudden high fevers, if not treated promptly, can easily cause harm to the patient's health. Therefore, this paper proposes a wearable temperature monitoring device to solve the above problems. Summary of the Invention
[0003] The purpose of this invention is to provide a wearable body temperature detection device to solve the problems existing in the prior art.
[0004] To achieve the above-mentioned technical objectives, the technical solution adopted by the present invention is as follows:
[0005] A wearable body temperature detection device includes an assembly box, a control terminal, an infrared temperature sensor, and a power supply assembly. An adaptive wearing component is mounted on the side of the assembly box, the control terminal is mounted on the lower side of the assembly box, the power supply assembly is mounted on the left side of the assembly box, the infrared temperature sensor is mounted on the front side of the assembly box, the front side of the assembly box has an opening, and a digital display screen, an indicator light, and a buzzer are mounted on the rear side of the assembly box. A fitting mechanism is mounted inside the assembly box.
[0006] The bonding mechanism includes a sliding plate, a micro servo motor, and a reduction gear assembly. The sliding plate is slidably mounted inside the assembly box. A heat-reducing patch is fixedly adhered to the front end of the sliding plate. The micro servo motor is fixedly mounted inside the assembly box. The reduction gear assembly is fixedly mounted to the micro servo motor. A rotating shaft is rotatably mounted inside the assembly box. The rotating shaft is driven by the reduction gear assembly and the micro servo motor. A screw is rotatably mounted inside the assembly box. A threaded cylinder that is threadedly connected to the screw is fixedly provided at the rear end of the sliding plate. The screw is driven by the rotating shaft.
[0007] Preferably, the deceleration assembly includes a deceleration box, which is fixedly mounted on the micro servo motor. Two double gears are rotatably mounted inside the deceleration box. A drive gear is rotatably mounted through the deceleration box at the output end of the micro servo motor. The drive gear meshes with the large gear of one of the double gears, and the small gear of one of the double gears meshes with the large gear of the other double gear. A driven gear is rotatably mounted through the deceleration box at the shaft, and the driven gear meshes with the small gear of the other double gear.
[0008] Preferably, both the rotating shaft and the screw are fixedly fitted with bevel gears, and the two bevel gears mesh with each other.
[0009] Preferably, the rear end of the slide plate is fixedly provided with a plurality of slide cylinders, and the inner side of the assembly box is fixedly provided with a plurality of slide rods corresponding one-to-one with the plurality of slide cylinders, and the plurality of slide rods are respectively slidably assembled on the inner side of the plurality of slide cylinders.
[0010] Preferably, the adaptive wearing component includes two elastic elastic straps, one end of each elastic elastic strap is fixedly mounted on the left and right sides of the assembly box, and the other end of each elastic elastic strap is fitted with a H-shaped adjustment buckle.
[0011] Preferably, the assembly box is further equipped with a winding mechanism, the winding mechanism including a splitting component and a winding component, the splitting component including a sliding cover, the sliding cover being slidably and interferometrically fitted to the upper end of the assembly box, the winding component including a winding roller, the winding roller being fixedly fitted to the end of the rotating shaft, the winding roller being equipped with a stabilizing member, a silicone film being attached to the front side of the heat-reducing patch, a traction belt being provided on the lower side of the silicone film, and the traction belt being sleeved on the winding roller.
[0012] Preferably, the stabilizing member includes a plurality of S-shaped elastic blocks, which are uniformly fixed to the winding roller.
[0013] Preferably, a slide bar is fixedly provided on both the left and right sides of the sliding cover, a slide groove is provided on the upper side of the assembly box to slide and match the slide bar, a limit groove is provided on the upper side of the slide groove, and a limit block is fixedly provided on the upper side of the slide bar to match the limit groove, and the limit block and the slide groove are interference-fitted.
[0014] Preferably, the control terminal includes a microcontroller, a switch module, and a delay module.
[0015] The benefits of this invention are that the device monitors the wearer's forehead temperature using an infrared temperature sensor. When the wearer's body temperature exceeds a preset line, the microcontroller controls the delay module to start. If the wearer's body temperature drops below the preset line during the delay period, the microcontroller interrupts and resets the delay module until the next activation. If the wearer's body temperature does not drop below the preset line during the delay period, the delay module transmits a signal to the microcontroller after the delay, and the microcontroller interrupts the delay module and runs an emergency cooling program. During this process, indicator lights and a buzzer are activated to warn caregivers or medical personnel. At the same time, a micro servo motor starts to control the sliding plate to attach the fever-reducing patch to the wearer's forehead, providing emergency treatment for fever and preventing a short-term rise in body temperature due to emotional excitement. Attached Figure Description
[0016] The present invention can be further illustrated by the non-limiting embodiments given in the accompanying drawings.
[0017] Figure 1 This is a schematic diagram of the structure of a wearable body temperature detection device according to the present invention. Figure 1 ;
[0018] Figure 2 This is a schematic diagram of the structure of a wearable body temperature detection device according to the present invention. Figure 2 ;
[0019] Figure 3 This is a cross-sectional structural diagram of a wearable body temperature detection device according to the present invention;
[0020] Figure 4 for Figure 3 Enlarged view of point A in the middle;
[0021] Figure 5 This is a partial structural schematic diagram of a wearable body temperature detection device according to the present invention;
[0022] Figure 6 for Figure 5 Enlarged view of point B in the middle;
[0023] Figure 7 This is a schematic diagram of the exploded structure of a wearable body temperature detection device according to the present invention;
[0024] Figure 8 for Figure 7 Enlarged view of point C in the middle;
[0025] Figure 9 This is a schematic diagram of the structure of a wearable body temperature detection device according to the present invention. Figure 3 ;
[0026] Figure 10 for Figure 9 Enlarged view of point D in the middle;
[0027] Figure 11 This is a flowchart of the present invention;
[0028] The symbols for the main components are explained below:
[0029] Assembly box 1, infrared temperature sensor 11, power supply assembly 12, digital display screen 13, slide plate 14, micro servo motor 141, rotating shaft 142, screw 143, threaded cylinder 144, indicator light 15, buzzer 16, heat-reducing patch 17, reduction gear box 21, double gear 22, driving gear 23, driven gear 24, bevel gear 25, slide cylinder 31, slide rod 32, elastic telescopic belt 41, H-shaped adjusting buckle 42, sliding cover 51, winding roller 52, silicone film 53, traction belt 54, S-shaped elastic block 55, slide bar 56, limit block 561, slide groove 57, limit groove 571. Detailed Implementation
[0030] To enable those skilled in the art to better understand the present invention, the technical solution of the present invention will be further described below in conjunction with the accompanying drawings and embodiments.
[0031] Example 1:
[0032] like Figure 1-2 As shown, a wearable body temperature detection device of the present invention includes an assembly box 1, a control terminal, an infrared temperature sensor 11, and a power supply assembly 12. An adaptive wearing component is mounted on the side of the assembly box 1. The adaptive wearing component includes two elastic elastic straps 41. One end of each elastic elastic strap 41 is fixedly mounted on the left and right sides of the assembly box 1, and the other end of each elastic elastic strap 41 is fitted with a H-shaped adjustment buckle 42. The adaptive wearing makes it easy for people to wear the device. The control terminal is mounted on the lower side of the assembly box 1. The power supply assembly 12 is mounted on the left side of the assembly box 1. The power supply assembly 12 can provide power to the electrical components of the device. The infrared temperature sensor 11 is mounted on the front side of the assembly box 1. The front side of the assembly box 1 is open. A digital display screen 13, an indicator light 15, and a buzzer 16 are mounted on the rear side of the assembly box 1. A fitting mechanism is mounted inside the assembly box 1.
[0033] like Figure 3-4As shown, the bonding mechanism includes a slide plate 14, a micro servo motor 141, and a reduction gear assembly. The slide plate 14 is slidably mounted on the inner side of the assembly box 1. Several slide cylinders 31 are fixedly provided at the rear end of the slide plate 14. Several slide rods 32, corresponding one-to-one with the slide cylinders 31, are fixedly provided on the inner side of the assembly box 1. The slide rods 32 are slidably mounted on the inner side of the slide cylinders 31, and the slide rods 32 and slide cylinders 31 are in a limiting sliding fit, allowing the slide plate 14 to slide only forward and backward. A heat-reducing patch 17 is fixedly adhered to the front end of the slide plate 14. The heat-reducing patch 17 can be attached to the slide plate 14 using double-sided tape or similar adhesive. It is easy to replace. The micro servo motor 141 is fixedly mounted inside the assembly box 1. The reduction assembly is fixedly mounted inside the micro servo motor 141. The rotating shaft 142 is rotatably mounted inside the assembly box 1. The rotating shaft 142 is connected to the micro servo motor 141 through the reduction assembly. The screw 143 is rotatably mounted inside the assembly box 1. The rear end of the slide plate 14 is fixedly provided with a threaded cylinder 144 that is threadedly connected to the screw 143. The screw 143 is connected to the rotating shaft 142. Both the rotating shaft 142 and the screw 143 are fixedly mounted with bevel gears 25. The two bevel gears 25 mesh with each other.
[0034] like Figure 5-6 As shown, the reduction assembly includes a reduction box 21, which is fixedly mounted on a micro servo motor 141. Two double gears 22 are rotatably mounted inside the reduction box 21. The output end of the micro servo motor 141 rotatably passes through the reduction box 21 and is fixedly mounted with a drive gear 23. The drive gear 23 meshes with the large gear of one of the double gears 22, and the small gear of one of the double gears 22 meshes with the large gear of the other double gear 22. The rotating shaft 142 rotatably passes through the reduction box 21 and is fixedly mounted with a driven gear 24. The driven gear 24 meshes with the small gear of the other double gear 22. The double gears 22 can reduce the speed provided by the micro servo motor 141 and increase the force output by the rotating shaft 142.
[0035] like Figure 11 The flowchart shown illustrates that the control terminal includes a microcontroller, a switch module, and a delay module. Infrared temperature sensor 11 monitors body temperature, and the monitoring data is displayed on digital display screen 13. The delay module acts as a delay mechanism to prevent temperature increases caused by emotional excitement in the wearer, reducing the probability of misjudgment of body temperature. The body temperature value monitored by infrared temperature sensor 11 is transmitted to the microcontroller for processing. If the body temperature remains above the warning line during the delay period, signal light 15 and buzzer 16 are triggered to remind the caregiver or medical staff. Simultaneously, the microcontroller controls the micro servo motor 141 to start, maneuvering the fever-reducing patch 17 close to the wearer's forehead for physical emergency cooling, reducing discomfort caused by high fever and preventing sudden high fever in the wearer.
[0036] When in use, the device is fitted with the assembly box 1 on the user's forehead via an adaptive wearing component. The device then operates by powering on the power component 12 via a switch module. At this time, the infrared temperature sensor 11 approaches the patient's forehead and monitors the patient's body temperature. The caregiver or medical staff can view the temperature at the wearer's forehead through the digital display screen 13. When the wearer's body temperature exceeds the preset temperature, the delay module is activated for monitoring. If the body temperature drops below the preset temperature line during the monitoring period of the delay module, the delay module is reset. If the body temperature remains above the preset temperature line during the monitoring period of the delay module, the signal light 15 and the buzzer 16 are triggered to remind the caregiver or medical staff. At the same time, the micro servo motor 141 starts and drives the rotating shaft 142 to rotate. The rotation of the rotating shaft 142 drives the screw 143 to rotate, thereby moving the slide plate 14 towards the wearer's forehead until the fever-reducing patch 17 is attached to the patient's forehead, providing emergency treatment and reducing the discomfort caused by high fever.
[0037] Example 2:
[0038] like Figure 7-10 As shown, the assembly box 1 is also equipped with a winding mechanism, which includes a splitting component and a winding component. The splitting component includes a sliding cover 51, which is slidably mounted on the upper end of the assembly box 1 with an interference fit. Sliding strips 56 are fixedly provided on both the left and right sides of the sliding cover 51. A sliding groove 57 is provided on the upper side of the assembly box 1 to slide and match the sliding strips 56. A limiting groove 571 is provided on the upper side of the sliding groove 57. A limiting block 561 matching the limiting groove 571 is fixedly provided on the upper side of the sliding strip 56. The limiting block 561 and the sliding groove 57 are interference fit. The sliding matching and winding assembly includes a winding roller 52, which is fixedly mounted on the end of the rotating shaft 142. The winding roller 52 is equipped with a stabilizing member, which includes a plurality of S-shaped elastic blocks 55. The plurality of S-shaped elastic blocks 55 are evenly fixed on the winding roller 52. The S-shaped elastic blocks 55 can elastically fix the sleeved traction belt 54 to enhance its stability. A silicone film 53 is attached to the front side of the heat-reducing patch 17. A traction belt 54 is provided on the lower side of the silicone film 53. The traction belt 54 is sleeved on the winding roller 52.
[0039] As the slide plate 14 moves forward, the winding roller 52 can wind up the silicone film 53 via the traction belt 54, exposing the cooling end of the heat-reducing patch 17. This achieves a simple structure and enables rapid winding of the silicone film 53. The silicone film 53 can cover and protect the gel end of the heat-reducing patch 17 used for cooling, preventing it from being contaminated before use. After winding, the silicone film 53 can be removed from the winding roller 52 for reuse, improving resource utilization.
[0040] The above embodiments are merely illustrative of the principles and effects of the present invention and are not intended to limit the invention. Any person skilled in the art can modify or alter the above embodiments without departing from the spirit and scope of the present invention. Therefore, all equivalent modifications or alterations made by those skilled in the art without departing from the spirit and technical concept disclosed in the present invention should still be covered by the claims of the present invention.
Claims
1. A wearable body temperature detection device, comprising an assembly box, a control terminal, an infrared temperature sensor, and a power supply assembly, wherein an adaptive wearing component is mounted on the side of the assembly box, characterized in that: The control terminal is mounted on the lower side of the assembly box, the power supply assembly is mounted on the left side of the assembly box, the infrared temperature sensor is mounted on the front side of the assembly box, the front side of the assembly box has an opening, the rear side of the assembly box is equipped with a digital display screen, an indicator light and a buzzer, and the assembly box is equipped with a bonding mechanism inside. The bonding mechanism includes a sliding plate, a micro servo motor, and a reduction gear assembly. The sliding plate is slidably mounted on the inside of the assembly box. A heat-reducing patch is fixedly adhered to the front end of the sliding plate. The micro servo motor is fixedly mounted inside the assembly box. The reduction gear assembly is fixedly mounted on the micro servo motor. A rotating shaft is rotatably mounted inside the assembly box. The rotating shaft is driven by the micro servo motor through the reduction gear assembly. A screw is rotatably mounted inside the assembly box. A threaded cylinder that is threadedly connected to the screw is fixedly provided at the rear end of the sliding plate. The screw is driven by the rotating shaft. The assembly box is also equipped with a winding mechanism, which includes a splitting component and a winding component. The splitting component includes a sliding cover, which is slidably and interferometrically fitted to the upper end of the assembly box. The winding component includes a winding roller, which is fixedly fitted to the end of the rotating shaft. The winding roller is equipped with a stabilizing member. A silicone film is attached to the front side of the heat-reducing patch, and a traction belt is provided on the lower side of the silicone film. The traction belt is sleeved on the winding roller. The stabilizing component includes a plurality of S-shaped elastic blocks, which are uniformly fixed to the winding roller. The sliding cover is fixedly provided with slide bars on both the left and right sides. The upper side of the assembly box is provided with a slide groove that slides and matches the slide bar. A limit groove is provided on the upper side of the slide groove. A limit block that matches the limit groove is fixedly provided on the upper side of the slide bar. The limit block and the slide groove are interference-fitted.
2. The wearable body temperature detection device according to claim 1, characterized in that: The deceleration assembly includes a deceleration box, which is fixedly mounted on the micro servo motor. Two double gears are rotatably mounted inside the deceleration box. A drive gear is rotatably mounted through the deceleration box at the output end of the micro servo motor. The drive gear meshes with the large gear of one of the double gears, and the small gear of one of the double gears meshes with the large gear of the other double gear. A driven gear is rotatably mounted through the deceleration box at the shaft, and the driven gear meshes with the small gear of the other double gear.
3. The wearable body temperature detection device according to claim 1, characterized in that: Both the rotating shaft and the screw are fixedly fitted with bevel gears, and the two bevel gears mesh with each other.
4. The wearable body temperature detection device according to claim 1, characterized in that: The rear end of the slide plate is fixedly provided with several slide cylinders, and the inner side of the assembly box is fixedly provided with several slide rods that correspond one-to-one with the slide cylinders. The slide rods are slidably assembled on the inner side of the slide cylinders respectively.
5. A wearable body temperature detection device according to claim 1, characterized in that: The adaptive wearing component includes two elastic elastic straps, one end of which is fixedly mounted on the left and right sides of the assembly box, and the other end of each elastic elastic strap is fitted with a H-shaped adjustment buckle.
6. The wearable body temperature detection device according to claim 1, characterized in that: The control terminal includes a microcontroller, a switch module, and a delay module.