A patient remote monitoring device

By designing a remote patient monitoring device with components such as mounting sleeves, insertion blocks, and connectors, the installation and maintenance process of vital sign monitoring radar is simplified, solving the problem of cumbersome operation in existing technologies, improving the efficiency of loading, unloading, replacement, and maintenance, and enhancing the effectiveness and convenience of monitoring.

CN224369852UActive Publication Date: 2026-06-19TAIHE HOSPITAL OF SHIYAN CITY (AFFILIATED HOSPITAL OF HUBEI UNIVERSITY OF MEDECINE)

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
TAIHE HOSPITAL OF SHIYAN CITY (AFFILIATED HOSPITAL OF HUBEI UNIVERSITY OF MEDECINE)
Filing Date
2025-04-03
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

The existing remote patient monitoring devices are fixed with multiple bolts, which makes operation cumbersome and time-consuming when the equipment fails, affecting the efficiency of installing, removing, replacing and repairing the vital signs monitoring radar.

Method used

The design incorporates an installation sleeve, insertion block, connector, rotating frame, support frame, vital sign monitoring radar, fixing components, limiting components, and adjustment components. The snap-fit ​​and rotating structure simplifies the installation and disassembly of the vital sign monitoring radar, while the limiting and adjustment components allow for angle adjustment, enabling convenient installation and maintenance.

Benefits of technology

The process of installing, replacing, and maintaining vital signs monitoring radar has been simplified, improving operational efficiency and ease of use, enhancing the effectiveness and accuracy of monitoring, and increasing the work efficiency of medical staff.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model relates to the field of medical apparatus and instruments especially is a patient remote monitoring device, the utility model provides a patient remote monitoring device that can install the sign monitoring radar to the patient and carry out detection use, simple operation saves time, and the sign monitoring radar is convenient for the loading and unloading, replacement and maintenance, improves the replacement efficiency and the convenience of use. A patient remote monitoring device, including installation cover, insert block and connecting piece etc.
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Description

Technical Field

[0001] This utility model relates to the field of medical devices, and in particular to a remote patient monitoring device. Background Technology

[0002] Remote patient monitoring is a method of remotely tracking and managing a patient's health status through technological means. It utilizes various digital technologies and devices, such as wearable devices, mobile health applications, and home medical devices, to collect the patient's health data and transmit this information to healthcare providers for evaluation and response.

[0003] Existing remote patient monitoring typically involves mounting remote monitoring equipment on a wall to monitor a patient's heart rate and respiratory status. However, current equipment is fixed in place with multiple bolts. When the equipment malfunctions, manual removal and installation require the use of auxiliary tools to reverse the bolts. This process is cumbersome, time-consuming, and inconvenient for the installation, removal, replacement, and maintenance of vital sign monitoring radars, affecting replacement efficiency and making the equipment extremely inconvenient to use.

[0004] Therefore, it is necessary to design a remote patient monitoring device that can be installed with a vital signs monitoring radar for patient detection, is simple to operate, saves time, facilitates the installation, removal, replacement and maintenance of the vital signs monitoring radar, and improves replacement efficiency and ease of use. Summary of the Invention

[0005] To overcome the shortcomings of current equipment that is installed and fixed with multiple bolts, requiring manual intervention with auxiliary tools to reverse the bolts to remove and install the equipment when it malfunctions, which is cumbersome, time-consuming, and inconvenient for the installation, removal, replacement, and maintenance of vital sign monitoring radar, thus affecting replacement efficiency, this utility model provides a remote patient monitoring device that can be installed with a vital sign monitoring radar for patient detection. It is simple to operate, saves time, facilitates the installation, removal, replacement, and maintenance of the vital sign monitoring radar, and improves replacement efficiency and ease of use.

[0006] The technical implementation scheme of this utility model is as follows: A remote patient monitoring device includes an installation sleeve, an insertion block, a connector, a rotating frame, a support frame, a vital signs monitoring radar, a fixing component, a limiting component, and an adjusting component. The insertion block is snapped onto the installation sleeve. A connector is connected to the front side of the insertion block. A rotating frame is rotatably connected to the connector. A support frame is connected to the front side of the rotating frame. A vital signs monitoring radar is rotatably connected to the middle of the support frame. A fixing component for fixing the insertion block is provided at the lower part of the installation sleeve. A limiting component for limiting the angle of the rotating frame is provided between the connector and the rotating frame. An adjusting component for adjusting the angle of the vital signs monitoring radar is provided between the support frame and the vital signs monitoring radar.

[0007] In addition, it is particularly preferred that the mounting sleeve has two mounting holes, one on the left and one on the right.

[0008] Furthermore, it is particularly preferred that the fixing assembly includes a guide rod, a first limiting frame, and a first telescopic spring. The guide rod is connected to the lower part of the mounting sleeve, and the first limiting frame is slidably connected to the guide rod. The first limiting frame is slidably connected to the mounting sleeve, the first limiting frame is engaged with the insertion block, and the first limiting frame is connected to the mounting sleeve by a first telescopic spring.

[0009] Furthermore, it is particularly preferred that the lower part of the first limiting frame is provided with a handle.

[0010] Furthermore, it is particularly preferred that the limiting component includes a first meshing gear, a second meshing gear, and a second telescopic spring. The first meshing gear is connected to the right side of the connector, and the second meshing gear is slidably connected to the right side of the rotating frame. The second meshing gear meshes with the first meshing gear, and the second telescopic spring is connected between the second meshing gear and the rotating frame.

[0011] Furthermore, it is particularly preferred that the adjustment assembly includes a common gear, a second limiting frame, and a third telescopic spring. The common gear is connected to the rear of the vital signs monitoring radar, the second limiting frame is slidably connected to the upper part of the support frame, the second limiting frame is engaged with the common gear, and the third telescopic spring is connected between the second limiting frame and the support frame.

[0012] Beneficial effects: 1. This utility model allows the first limiting frame to be moved, and then the vital signs monitoring radar can be removed for replacement or repair. Then, the repaired or new vital signs monitoring radar can be installed on the mounting sleeve, so that the first limiting frame and the insertion block can be engaged. This enables the installation of the vital signs monitoring radar for patient detection. The operation is simple, saves time, and facilitates the installation, removal, replacement and repair of the vital signs monitoring radar, improving replacement efficiency and ease of use.

[0013] 2. This utility model uses a rotating frame to rotate and fix the support frame and the vital signs monitoring radar. After rotating the vital signs monitoring radar, it is fixed again. The patient's physiological parameters are then monitored by the vital signs monitoring radar. This allows for remote monitoring by adjusting the angle of the vital signs monitoring radar according to the patient's position, improving the effectiveness and accuracy of monitoring, enhancing patient safety, increasing the work efficiency of medical staff, and providing flexible use. Attached Figure Description

[0014] Figure 1 This is a three-dimensional structural diagram of the present invention.

[0015] Figure 2 This is a three-dimensional cross-sectional view of the insertion block and other components of this utility model.

[0016] Figure 3This is a three-dimensional cross-sectional view of the connectors and other components of this utility model.

[0017] Figure 4 This is a three-dimensional structural diagram of the rotating frame and other components of this utility model.

[0018] Figure 5 This is a three-dimensional cross-sectional view of a common gear or other component of this utility model.

[0019] The above-mentioned figures include the following reference numerals: 1. Mounting sleeve, 2. Insertion block, 3. Connector, 4. Guide rod, 5. First limiting frame, 6. First telescopic spring, 7. Rotating frame, 8. First meshing gear, 9. Second meshing gear, 10. Second telescopic spring, 11. Support frame, 12. Vital signs monitoring radar, 13. Ordinary gear, 14. Second limiting frame, 15. Third telescopic spring. Detailed Implementation

[0020] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0021] A remote patient monitoring device, such as Figures 1-5As shown, the device includes an installation sleeve 1, an insertion block 2, a connector 3, a rotating frame 7, a support frame 11, a vital signs monitoring radar 12, a fixing component, a limiting component, and an adjusting component. The installation sleeve 1 has two mounting holes on its left and right sides for easy installation and fixation. The insertion block 2 is snapped onto the installation sleeve 1. The connector 3 is connected to the front of the insertion block 2. The rotating frame 7 is rotatably connected to the connector 3. The support frame 11 is connected to the front of the rotating frame 7. The vital signs monitoring radar 12 is rotatably connected to the middle of the support frame 11. The lower part of the mounting sleeve 1 is provided with a fixing component for fixing the insertion block 2. The fixing component includes a guide rod 4, a first limiting frame 5, and a first telescopic spring 6. The guide rod 4 is connected to the lower part of the mounting sleeve 1, and the first limiting frame 5 is slidably connected to the guide rod 4. The first limiting frame 5 is slidably connected to the mounting sleeve 1 and is engaged with the insertion block 2. Each first limiting frame 5 has a handle at its lower part for easy gripping and pulling. A first telescopic spring 6 is connected between the connecting member 3 and the rotating frame 7. A limiting component for limiting the angle of the rotating frame 7 is provided between the connecting member 3 and the rotating frame 7. The limiting component includes a first meshing gear 8, a second meshing gear 9, and a second telescopic spring 10. The first meshing gear 8 is connected to the right side of the connecting member 3. The second meshing gear 9 is slidably connected to the right side of the rotating frame 7. The second meshing gear 9 meshes with the first meshing gear 8. The second telescopic spring 10 is connected between the second meshing gear 9 and the rotating frame 7. An adjustment component for adjusting the angle of the vital signs monitoring radar 12 is provided between the support frame 11 and the vital signs monitoring radar 12. The adjustment component includes a common gear 13, a second limiting frame 14, and a third telescopic spring 15. The common gear 13 is connected to the rear of the vital signs monitoring radar 12. The second limiting frame 14 is slidably connected to the upper part of the support frame 11. The second limiting frame 14 is engaged with the common gear 13. The third telescopic spring 15 is connected between the second limiting frame 14 and the support frame 11.

[0022] When remote patient monitoring is required, this device can be used. The insertion block 2 engages with the mounting sleeve 1, causing the first limiting frame 5 to move along the guide rod 4 and then reset to engage with the insertion block 2. The first telescopic spring 6 is compressed and then rebounds, thereby installing the connecting piece 3, the rotating frame 7, the support frame 11, and the vital signs monitoring radar 12 onto the mounting sleeve 1. Next, the mounting sleeve 1 is brought into contact with the wall, and the device is mounted on the wall using screws through the mounting holes on the mounting sleeve 1. Then, depending on the patient's lying posture and position, the second meshing gear 9 is manually pulled to disengage from the first meshing gear 8, causing the second telescopic spring 10 to be compressed. The pressure is applied, and then the rotating frame 7 is rotated, causing the support frame 11 and the vital signs monitoring radar 12 to rotate. After rotating to a suitable angle, the second meshing gear 9 is released, the second telescopic spring 10 rebounds, and the second meshing gear 9 moves in the opposite direction to reset and mesh with the first meshing gear 8 for limiting and fixing. Then, the vital signs monitoring radar 12 is rotated, causing the ordinary gear 13 to rotate, causing the second limiting frame 14 to move repeatedly and then reset to engage with the ordinary gear 13. The third telescopic spring 15 is compressed and then rebounds, thereby adjusting the angle of the vital signs monitoring radar 12. Subsequently, the vital signs monitoring radar 12 is activated to monitor the patient's physiological parameters such as respiration and heart rate. The monitored data is transmitted to a remote terminal for display, allowing for remote monitoring by adjusting the angle of the vital signs monitoring radar 12 according to the patient's position. This improves the effectiveness and accuracy of monitoring, enhances patient safety, increases the efficiency of medical staff, and provides flexible use. When the vital signs monitoring radar 12 malfunctions and needs repair or replacement, the first limiting frame 5 is moved away from the insertion block 2 by pulling the handle, compressing the first telescopic spring 6. Then, the insertion block 2 is removed, and the vital signs monitoring radar 12 is removed for replacement or repair. Releasing the handle causes the first telescopic spring 6 to return to its original position, and the first limiting frame 5 moves in the opposite direction to reset. The repaired vital signs monitoring radar 12 can then be repositioned. Radar 12 or a new vital signs monitoring radar 12 is installed on the mounting sleeve 1, so that the insertion block 2 is engaged with the mounting sleeve 1, and the first limiting frame 5 moves along the guide rod 4 and then resets to engage with the insertion block 2. The first telescopic spring 6 is compressed and then rebounds, thereby fixing the insertion block 2 and the vital signs monitoring radar 12 in place. This allows the vital signs monitoring radar 12 to be installed for patient monitoring. The operation is simple, saves time, and facilitates the installation, removal, replacement, and maintenance of the vital signs monitoring radar 12, improving the efficiency of replacement and the convenience of use. The vital signs monitoring radar 12 can then be used continuously. When not in use, the vital signs monitoring radar 12 can be turned off.

[0023] Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that variations may be made to these embodiments without departing from the principles and spirit of the present invention, the scope of which is defined by the appended claims and their equivalents.

Claims

1. A remote patient monitoring device, characterized in that: It includes an installation sleeve (1), an insertion block (2), a connector (3), a rotating frame (7), a support frame (11), a vital signs monitoring radar (12), a fixing component, a limiting component, and an adjusting component. The installation sleeve (1) is fitted with an insertion block (2). The front of the insertion block (2) is connected to a connector (3). The connector (3) is rotatably connected to the rotating frame (7). The front of the rotating frame (7) is connected to a support frame (11). The vital signs monitoring radar (12) is rotatably connected to the middle of the support frame (11). The lower part of the installation sleeve (1) is provided with a fixing component for fixing the insertion block (2). The connecting component (3) and the rotating frame (7) are provided with a limiting component for limiting the angle of the rotating frame (7). The support frame (11) and the vital signs monitoring radar (12) are provided with an adjusting component for adjusting the angle of the vital signs monitoring radar (12).

2. A patient remote monitoring device according to claim 1, characterized in that: The mounting sleeve (1) has two mounting holes on the left and right sides, one above the other.

3. A remote patient monitoring device according to claim 1, characterized in that: The fixing assembly includes a guide rod (4), a first limiting frame (5) and a first telescopic spring (6). The lower part of the mounting sleeve (1) is connected to the guide rod (4), and the first limiting frame (5) is slidably connected to the guide rod (4). The first limiting frame (5) is slidably connected to the mounting sleeve (1), and the first limiting frame (5) is snapped into the insertion block (2). The first limiting frame (5) is connected to the mounting sleeve (1) by the first telescopic spring (6).

4. A patient remote monitoring device according to claim 3, characterized in that: The first restraint frame (5) is equipped with a handle at the bottom.

5. A patient remote monitoring device according to claim 1, characterized in that: The limiting assembly includes a first meshing gear (8), a second meshing gear (9), and a second telescopic spring (10). The first meshing gear (8) is connected to the right side of the connector (3), and the second meshing gear (9) is slidably connected to the right side of the rotating frame (7). The second meshing gear (9) meshes with the first meshing gear (8), and the second telescopic spring (10) is connected between the second meshing gear (9) and the rotating frame (7).

6. A patient remote monitoring device according to claim 1, characterized in that: The adjustment assembly includes a common gear (13), a second limiting frame (14) and a third telescopic spring (15). The common gear (13) is connected to the rear of the vital signs monitoring radar (12). The second limiting frame (14) is slidably connected to the upper part of the support frame (11). The second limiting frame (14) is engaged with the common gear (13). The third telescopic spring (15) is connected between the second limiting frame (14) and the support frame (11).