Air bag cervical traction fixator for collecting human health data

By incorporating sensors and a control system into the air-cushioned cervical traction fixation device, the problem of the inability to collect health data in existing technologies has been solved, achieving the effect of real-time monitoring and storage of human health data while treating cervical spine diseases.

CN224345054UActive Publication Date: 2026-06-12HANGZHOU FANGXIANG MEDICAL DEVICES CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HANGZHOU FANGXIANG MEDICAL DEVICES CO LTD
Filing Date
2025-01-06
Publication Date
2026-06-12

AI Technical Summary

Technical Problem

Existing air-cushioned cervical traction devices have limited functionality and cannot collect human health data while treating cervical spine diseases.

Method used

An airbag cervical traction fixation device was designed, which incorporates a photoelectric sensor, an LED light source, a heart rate sensor, and an acceleration sensor. The control system monitors blood oxygen saturation, blood pressure, heart rate, and sleep status in real time and sends the data to the user terminal for storage. Adjustable parts to fit different body types ensure accurate data collection.

Benefits of technology

It enables the real-time collection and monitoring of human health data, including blood oxygen saturation, blood pressure, heart rate, and sleep patterns, while treating cervical spine diseases. The data is highly accurate and easy to store.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses an air bag cervical vertebra traction fixer of collection human health data belongs to medical instrument technical field, including air bag cervical vertebra traction fixer body, the inside of air bag cervical vertebra traction fixer body is provided with support, is provided with mounting bracket in the support, mounting bracket and support sliding fit, be provided with the adjusting part for adjusting mounting bracket movement in the support, the inside of mounting bracket is provided with control system, the side away from the support of mounting bracket is installed with photoelectric sensor, LED light source, heart rate sensor and acceleration sensor, photoelectric sensor, LED light source, heart rate sensor and acceleration sensor all with control system electric connection, can realize the health data of real -time collection human in the treatment cervical vertebra disease simultaneously.
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Description

Technical Field

[0001] This utility model relates to the field of medical device technology, and more specifically, to an airbag cervical traction fixation device for collecting human health data. Background Technology

[0002] Treatment methods for cervical spondylosis are divided into non-surgical and surgical treatments. Traction is the main non-surgical method for relieving symptoms of cervical spondylosis. Effective traction can relieve neck muscle spasms, alleviate pain symptoms, increase the intervertebral space and intervertebral foramen, help stabilize the protruding nucleus pulposus and annulus fibrosus, relieve nerve root compression and irritation, promote the absorption of nerve root edema, relieve vertebral artery compression, promote blood circulation, help reduce local congestion, swelling and hyperplasia, loosen adhesions in the joint capsule, improve and restore uncovertebral joints, adjust facet joint misalignment and vertebral slippage, adjust and restore the damaged internal and external balance of the cervical spine, and restore the normal function of the cervical spine.

[0003] Existing air-cushioned cervical traction devices have relatively limited functions, only providing support and protection for the cervical spine. However, with people's increasing pursuit of health, there is a desire to collect and record human health data while treating cervical spine diseases. To address these needs, the following solution is proposed. Utility Model Content

[0004] In view of the problems existing in the prior art, the purpose of this utility model is to provide an airbag cervical traction fixation device for collecting human health data, which can collect human health data in real time while treating cervical spine diseases.

[0005] To solve the above problems, the present invention adopts the following technical solution.

[0006] A pneumatic cervical traction fixation device for collecting human health data includes a pneumatic cervical traction fixation device body. A bracket is provided on the inner side of the pneumatic cervical traction fixation device body, and a mounting frame is provided inside the bracket. The mounting frame and the bracket are slidably engaged. An adjustment component for adjusting the movement of the mounting frame is provided inside the bracket. A control system is provided inside the mounting frame. A photoelectric sensor, an LED light source, a heart rate sensor, and an acceleration sensor are installed on the side of the mounting frame away from the bracket. The photoelectric sensor, the LED light source, the heart rate sensor, and the acceleration sensor are all electrically connected to the control system.

[0007] Preferably, the adjusting component includes a threaded rod, a movable block, and a push rod. Two threaded rods are provided, their ends fixedly connected, and rotatably arranged inside the bracket. The threads of the two threaded rods are in opposite directions. Two movable blocks are provided, each sleeved on a threaded rod, with the movable block and threaded rod threadedly engaged. Two push rods are provided, arranged symmetrically, and rotatably positioned on top of the two movable blocks. The other ends of the two push rods rotatably engage with the bottom of the mounting bracket.

[0008] Preferably, the control system includes a power supply, a control panel, a Bluetooth transmission module, and a data processing chip, all of which are electrically connected to the control panel.

[0009] Preferably, stabilizing components are symmetrically arranged on both sides of the adjusting component. Each stabilizing component includes an outer tube and a support rod. The outer tube is fixedly installed inside the bracket, and the outer tube and the bracket are perpendicular to each other. The support rod is slidably arranged at one end of the outer tube, and the other end of the support rod is fixedly connected to the bottom of the mounting bracket.

[0010] Preferably, the side of the airbag cervical traction fixation device body is provided with an installation hole, and a locking block is installed at the bottom of the bracket, the locking block and the installation hole are engaged.

[0011] Preferably, an adjustment knob is provided on one side of the bracket, one end of the adjustment knob passes through the bracket and is fixedly connected to one end of the threaded rod, and the adjustment knob and the bracket are rotatably engaged.

[0012] Preferably, the power source is a rechargeable battery.

[0013] Compared with existing technologies, the advantages of this utility model are:

[0014] I. This solution uses an airbag cervical traction fixation device to treat cervical spine diseases. Through the combination of LED light source and photoelectric sensors, it can monitor blood oxygen saturation, blood pressure, and heart rate. The heart rate sensor can simultaneously monitor the heart rate, and the monitoring results from the heart rate sensor and photoelectric sensor are mutually verified. The heart rate sensor, in conjunction with an accelerometer, can also provide feedback on the user's sleep status. The control system processes the data and sends it to the user's terminal for storage. Adjustable components allow for adjustment of the mounting frame's position, adapting it to the needs of different body types and ensuring a close fit to the user's neck skin, guaranteeing accurate data collection.

[0015] Second, by rotating two threaded rods with opposite thread directions, the corresponding moving block can be moved. The moving block will move one end of the corresponding push rod, that is, the angle of the push rod relative to the threaded rod will change. Since the length of the push rod is fixed, when the angle of the push rod changes, the distance between the end of the push rod connected to the mounting bracket and the threaded rod will change. This is used to adjust the positional relationship between the mounting bracket and the support, ensuring that the mounting bracket fits snugly against the skin of the human body.

[0016] 3. The power supply provides power to the control panel, the data processing chip processes the monitoring data from the photoelectric sensor, heart rate sensor, and accelerometer, and the Bluetooth module sends the processed data to the user terminal for storage.

[0017] Fourth, the sliding fit between the outer sleeve and the support rod is used to limit the movement of the mounting bracket and ensure the stability of the mounting bracket's movement.

[0018] Fifth, by using the mounting holes and locking blocks, the bracket and the airbag cervical traction fixation device can be connected and disassembled, thus facilitating maintenance.

[0019] 6. The adjustment knob allows users to easily rotate the threaded rod for adjustment.

[0020] 7. Rechargeable batteries can be charged directly, eliminating the hassle of replacing batteries. Attached Figure Description

[0021] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0022] Figure 2 This is a structural schematic diagram of the bracket and mounting frame of this utility model;

[0023] Figure 3 This is a cross-sectional view of the bracket and mounting frame of this utility model;

[0024] Figure 4 This is a schematic diagram of the moving block and push rod of this utility model;

[0025] Figure 5 This is a cross-sectional structural diagram of the stabilizing component of this utility model;

[0026] Figure 6 This is a schematic diagram of the connection structure between the adjustment knob and the threaded rod of this utility model.

[0027] Explanation of the labels in the diagram:

[0028] 1. Airbag cervical traction fixation device body; 2. Bracket; 3. Mounting frame; 4. Adjustment component; 5. Control system; 6. Photoelectric sensor; 7. LED light source; 8. Heart rate sensor; 9. Accelerometer; 10. Threaded rod; 11. Moving block; 12. Push rod; 13. Power supply; 14. Control panel; 15. Bluetooth transmission module; 16. Data processing chip; 17. Stabilizing component; 18. Outer tube; 19. Support rod; 20. Mounting hole; 21. Locking block; 22. Adjustment knob. Detailed Implementation

[0029] Example 1:

[0030] Please see Figure 1-6 An airbag cervical traction fixation device for collecting human health data includes an airbag cervical traction fixation device body 1, a bracket 2 provided on the inner side of the airbag cervical traction fixation device body 1, an installation hole 20 provided on the side of the airbag cervical traction fixation device body 1, and a locking block 21 installed at the bottom of the bracket 2. The locking block 21 and the installation hole 20 are engaged. Through the cooperation of the installation hole 20 and the locking block 21, the bracket 2 and the airbag cervical traction fixation device body 1 can be connected and disassembled, thereby facilitating maintenance.

[0031] The bracket 2 is equipped with a mounting frame 3, which is slidably fitted to the bracket 2. The mounting frame 3 is symmetrically equipped with stabilizing components 17, which include an outer tube 18 and a support rod 19. The outer tube 18 is fixedly installed inside the bracket 2 and is perpendicular to the bracket 2. The support rod 19 is slidably arranged at one end of the outer tube 18 and the other end of the support rod 19 is fixedly connected to the bottom of the mounting frame 3. The sliding fit between the outer tube 18 and the support rod 19 is used to limit the movement of the mounting frame 3 and ensure the stability of the movement of the mounting frame 3.

[0032] The bracket 2 is equipped with an adjustment component 4 for adjusting the movement of the mounting bracket 3. The adjustment component 4 includes a threaded rod 10, a moving block 11, and a push rod 12. There are two threaded rods 10, and their ends are fixedly connected. The two threaded rods 10 are rotatably arranged inside the bracket 2. An adjustment knob 22 is provided on one side of the bracket 2. One end of the adjustment knob 22 passes through the bracket 2 and is fixedly connected to one end of the threaded rod 10. The adjustment knob 22 and the bracket 2 are rotatably engaged. The adjustment knob 22 allows the user to rotate the threaded rod 10 for adjustment. The threads of the two threaded rods 10 are opposite. There are two moving blocks 11, and each moving block 11 is fitted onto the threaded rod 10. The moving block 11 and the threaded rod 10 are threadedly engaged. There are two push rods 12, and they are symmetrically arranged. The two push rods 12 are rotatably arranged on top of the two moving blocks 11. The other end of the two push rods 12 is rotatably engaged with the bottom of the mounting bracket 3.

[0033] Rotating the two threaded rods 10 with opposite thread directions causes them to rotate, which in turn moves the corresponding moving block 11. The moving block 11 then moves one end of the corresponding push rod 12, causing the angle of the push rod 12 relative to the threaded rod 10 to change. Since the length of the push rod 12 is fixed, when the angle of the push rod 12 changes, the distance between the end of the push rod 12 connected to the mounting bracket 3 and the threaded rod 10 changes. This is used to adjust the positional relationship between the mounting bracket 3 and the support 2, ensuring that the mounting bracket 3 fits snugly against the skin of the human body.

[0034] The mounting bracket 3 houses a control system 5, which includes a power supply 13, a control panel 14, a Bluetooth transmission module 15, and a data processing chip 16. The power supply 13, Bluetooth transmission module 15, and data processing chip 16 are all electrically connected to the control panel 14. The power supply 13 is a rechargeable battery, which can be directly charged without the hassle of battery replacement. A through-slot is provided on the surface of the bracket 2 for charging the battery. The power supply 13 provides power to the control panel 14. The data processing chip 16 processes monitoring data from the photoelectric sensor 6, heart rate sensor 8, and accelerometer 9. The Bluetooth module transmits the processed data to the user terminal for storage.

[0035] The mounting bracket 3 houses an accelerometer 9. A photoelectric sensor 6, an LED light source 7, and a heart rate sensor 8 are mounted on the side away from the bracket 2. A transparent glass panel is mounted on one side of the mounting bracket 3. This transparent glass prevents the photoelectric sensor 6, LED light source 7, and heart rate sensor 8 from directly contacting the human body, thus providing protection. Simultaneously, the transparent design ensures that the photoelectric sensor 6, LED light source 7, and heart rate sensor 8 can detect human skin, guaranteeing accurate detection. The photoelectric sensor 6, heart rate sensor 8, and accelerometer 9 are all electrically connected to the processing chip, and the LED light source 7 is electrically connected to the control panel 14.

[0036] Working principle:

[0037] In use, the airbag cervical traction fixation device body 1 is installed on the cervical spine of the human body. The airbag cervical traction fixation device body 1 is used to treat the cervical spine problems of the human body. At the same time, by rotating the adjustment knob 22, the adjustment knob 22 will drive the threaded rod 10 to rotate. Since the threads of the two threaded rods 10 are opposite, when the threaded rods 10 rotate, the two threaded rods 10 will drive the corresponding moving blocks 11 to move in opposite directions, thereby driving one end of the push rod 12 to move. That is, the push rod 12 will push the mounting frame 3 to move, and the mounting frame 3 will drive the glass to move, so that the glass is in close contact with the skin, allowing the photoelectric sensor 6, heart rate sensor 8 and LED light source 7 to act on the human body's skin.

[0038] Taking advantage of the different absorption rates of red and infrared light by oxygenated hemoglobin (HbO2) and non-oxygenated hemoglobin (Hb) in the human body, the LED light source 7 uses red light with a wavelength of 660nm and near-infrared light with a wavelength of 940nm as the light source. The photoelectric sensor 6 measures the light transmission intensity of human tissue to calculate blood oxygen concentration and blood oxygen saturation. The photoelectric sensor 6 can also collect pulse waves from the neck and estimate blood pressure data by analyzing the pulse waves. Changes in blood flow caused by the light emitted by the LED light source 7 shining on the skin will cause changes in the intensity of the light reflected back to the photoelectric sensor 6, thereby monitoring the heart rate.

[0039] Heart rate sensor 8 can directly capture electrocardiogram signals. The monitoring results of heart rate sensor 8 and photoelectric sensor 6 are used for complementary verification to ensure accuracy. Heart rate sensor 8 is used to monitor the user's heart rate changes in real time. Heart rate changes are closely related to sleep state. For example, the heart rate is usually low and stable during deep sleep, while the heart rate may increase during rapid eye movement (REM) sleep. Through heart rate data, the bracelet can more accurately determine the user's sleep stage and sleep quality. Accelerometer sensor 9 can measure the user's neck movements during sleep, including turning over and moving. By analyzing these movement data, accelerometer sensor 9 can preliminarily determine the user's sleep state, such as falling asleep, light sleep, deep sleep, and waking up.

[0040] The data processing chip 16 is used to process the monitoring data from the photoelectric sensor 6, heart rate sensor 8, and accelerometer 9, and the Bluetooth module is used to send the processed data to the user terminal for storage.

Claims

1. A pneumatic cervical traction fixation device for collecting human health data, characterized in that: The device includes an airbag cervical traction fixation body (1), a bracket (2) is provided on the inner side of the airbag cervical traction fixation body (1), a mounting frame (3) is provided inside the bracket (2), the mounting frame (3) and the bracket (2) are slidably engaged, an adjustment component (4) for adjusting the movement of the mounting frame (3) is provided inside the bracket (2), a control system (5) is provided inside the mounting frame (3), and a photoelectric sensor (6), an LED light source (7), a heart rate sensor (8) and an acceleration sensor (9) are installed on the side of the mounting frame (3) away from the bracket (2), and the photoelectric sensor (6), the LED light source (7), the heart rate sensor (8) and the acceleration sensor (9) are all electrically connected to the control system (5).

2. The airbag cervical traction fixation device for collecting human health data according to claim 1, characterized in that: The adjusting component (4) includes a threaded rod (10), a moving block (11), and a push rod (12). There are two threaded rods (10), and the ends of the two threaded rods (10) are fixedly connected. The two threaded rods (10) are rotatably arranged inside the bracket (2), and the threads of the two threaded rods (10) are opposite. There are two moving blocks (11), and the two moving blocks (11) are respectively sleeved on the threaded rods (10). The moving blocks (11) and the threaded rods (10) are threadedly engaged. There are two push rods (12), and the two push rods (12) are symmetrically arranged. The two push rods (12) are rotatably arranged on the top of the two moving blocks (11), and the other ends of the two push rods (12) are rotatably engaged with the bottom of the mounting bracket (3).

3. The airbag cervical traction fixation device for collecting human health data according to claim 1, characterized in that: The control system (5) includes a power supply (13), a control panel (14), a Bluetooth transmission module (15), and a data processing chip (16), all of which are electrically connected to the control panel (14).

4. The airbag cervical traction fixation device for collecting human health data according to claim 1, characterized in that: The adjusting component (4) is symmetrically provided with stabilizing components (17) on both sides. The stabilizing component (17) includes an outer tube (18) and a support rod (19). The outer tube (18) is fixedly installed inside the bracket (2) and the outer tube (18) and the bracket (2) are perpendicular to each other. The support rod (19) is slidably arranged at one end of the outer tube (18) and the other end of the support rod (19) is fixedly connected to the bottom of the mounting bracket (3).

5. The airbag cervical traction fixation device for collecting human health data according to claim 1, characterized in that: The airbag cervical traction fixation device body (1) has an installation hole (20) on its side, and a locking block (21) is installed at the bottom of the bracket (2), and the locking block (21) and the installation hole (20) are engaged.

6. The airbag cervical traction fixation device for collecting human health data according to claim 2, characterized in that: An adjustment knob (22) is provided on one side of the bracket (2). One end of the adjustment knob (22) passes through the bracket (2) and is fixedly connected to one end of the threaded rod (10). The adjustment knob (22) and the bracket (2) are rotatably engaged.

7. The airbag cervical traction fixation device for collecting human health data according to claim 3, characterized in that: The power source (13) is a rechargeable battery.