Medical scaffold device
By combining an automatic lifting mechanism with a temperature sensor, intelligent control of the medical scaffold device is achieved, solving the problems of temperature monitoring and inconvenient operation of existing devices, meeting the diverse treatment needs of postoperative patients, and improving treatment efficiency and comfort.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 晋江市医院(上海市第六人民医院福建医院)
- Filing Date
- 2025-03-12
- Publication Date
- 2026-07-03
AI Technical Summary
Existing medical scaffold devices lack temperature control and monitoring functions, are inconvenient to operate, and have a low level of intelligence, making it difficult to meet the diverse treatment needs of postoperative patients.
It adopts an automatic lifting mechanism to adjust the height of the arm guard and medical heat lamp, and is equipped with temperature sensing patches and a control cabinet to realize temperature monitoring and alarm functions, and is intelligently controlled by a remote control device.
It has improved treatment efficiency, met the needs of different patients and treatment stages, reduced the burden on medical staff, and improved patient comfort and treatment outcomes.
Smart Images

Figure CN224441930U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of medical equipment technology, specifically a medical scaffold device. Background Technology
[0002] Postoperative rehabilitation of the arm is a crucial aspect of medical care, especially for patients undergoing fracture reduction, surgical wound healing, or skin tissue repair. Postoperative recovery relies not only on arm immobilization and support but also on effective temperature control and thermotherapy to promote blood circulation and tissue repair. Furthermore, medical staff need to monitor the patient's recovery status in real time, particularly the skin temperature after bandage or plaster cast application, as this is essential for assessing wound infection risk and adjusting care plans. However, existing medical arm frames are largely limited to providing immobilization and support, making it difficult to meet the diverse needs of postoperative treatment.
[0003] Defects and shortcomings of existing technology:
[0004] 1. Lack of temperature monitoring function: Existing equipment usually does not have the ability to monitor temperature in real time and cannot assess the temperature status of the patient's skin after wrapping with sandpaper or plaster.
[0005] 2. Inconvenient operation: Traditional hand scaffolding devices require manual operation to adjust the height and angle of the guard plate, which is not only time-consuming and laborious, but also easily affects the treatment efficiency. In addition, the fixed angle and fixed temperature structure of ordinary medical lamps are difficult to meet the needs of different patients and treatment stages.
[0006] 3. Low level of intelligence: Most medical scaffold devices lack sensors and control modules, making it impossible to collect data and provide intelligent reminders, which increases the burden on medical staff. Utility Model Content
[0007] The technical problem to be solved by this utility model is to provide a medical scaffold device that addresses the shortcomings of the prior art. The height of the medical heating lamp device and the arm guard device in this medical scaffold device are adjusted by an automatic lifting mechanism, eliminating the need for manual operation and saving time and effort. The angle and temperature of the medical heating lamp are adjustable to meet the needs of different patients and treatment stages. The temperature sensing patch can collect the temperature status of the patient's skin, and the control cabinet and temperature alarm can realize the overheating alarm function, reducing the burden on medical staff.
[0008] To achieve the above-mentioned technical objectives, the technical solution adopted by this utility model is as follows:
[0009] A medical arm scaffold device includes a medical heat lamp device, an arm guard device, and a housing base;
[0010] The arm guard device includes an upper arm guard, a lower arm guard, a guard linkage mechanism, a cylindrical locking mechanism, and a motor. One end of the guard linkage mechanism is connected to the cylindrical locking mechanism, and the other end is connected to the housing of the motor. The upper arm guard is fixedly connected with rod 1 and rod 2, and the lower arm guard is fixedly connected with rod 3 and rod 4. Rod 1 on the upper arm guard is connected to the housing of the motor. Rod 2 on the upper arm guard and rod 4 on the lower arm guard are rotatably connected. Rod 3 on the lower arm guard is connected to the output end of the motor.
[0011] The medical heating lamp device includes a medical heating lamp, a heating lamp linkage mechanism, a temperature control switch, and a cylindrical locking mechanism II. The medical heating lamp is connected to one end of the heating lamp linkage mechanism, the other end of the heating lamp linkage mechanism is connected to the housing of the temperature control switch, and the housing of the temperature control switch is connected to the cylindrical locking mechanism II.
[0012] The aforementioned housing base includes a housing, an automatic lifting mechanism, a control cabinet, and a temperature alarm. The automatic lifting mechanism, control cabinet, and temperature alarm are all connected to the housing. The first cylindrical locking mechanism and the second cylindrical locking mechanism are both locked to the lifting rod of the automatic lifting mechanism. The temperature sensing patch and temperature control switch used to collect the patient's arm skin temperature are both connected to the control cabinet. The control cabinet is connected to the temperature alarm, the automatic lifting mechanism, the first motor, and the medical heating lamp.
[0013] As a further improvement of the present invention, the guard plate linkage mechanism includes a first linkage and a second linkage. One end of the first linkage is connected to the housing of a first motor, and one end of the second linkage is connected to a first cylindrical locking mechanism. The other ends of the first linkage and the second linkage are locked together by a rotary locking mechanism.
[0014] As a further improved technical solution of this utility model, the heating lamp linkage mechanism includes a lower rod seat, a middle rod seat, an upper rod seat, an upper lamp rod one, an upper lamp rod two, a lower lamp rod one, a lower lamp rod two, a lower cylinder support rod, and an upper cylinder support rod. The lower rod seat is fixedly connected to the top of the temperature control switch housing. The lower rod seat and the middle rod seat are rotatably connected through the lower lamp rod one and the lower lamp rod two, and one end of the lower lamp rod one is locked to the middle rod seat through a rotary locking mechanism. The middle rod seat and the upper rod seat are rotatably connected through the upper lamp rod one and the upper lamp rod two, and one end of the upper lamp rod two is locked to the upper rod seat through a rotary locking mechanism. One end of the lower cylinder support rod is rotatably connected to the lower rod seat, and the other end is rotatably connected to the lower lamp rod one. One end of the upper cylinder support rod is rotatably connected to the middle rod seat, and the other end is rotatably connected to the upper lamp rod one. The medical heating lamp is locked to the upper rod seat through a rotary locking mechanism.
[0015] As a further improvement of this utility model, both the first cylindrical locking mechanism and the second cylindrical locking mechanism are locked to the support rod, and the support rod is connected to the lifting rod of the automatic lifting mechanism.
[0016] As a further improvement to this utility model, the automatic lifting mechanism adopts a screw jack.
[0017] As a further improvement of this utility model, the first cylindrical locking mechanism and the second cylindrical locking mechanism adopt cylindrical clamps.
[0018] As a further improvement of this utility model, the bottom of the box is provided with casters.
[0019] As a further improvement of this utility model, a remote control device is also included, which is wirelessly connected to the control cabinet.
[0020] As a further improvement of this utility model, the rotary locking mechanism adopts a locking bolt.
[0021] The beneficial effects of this utility model are as follows:
[0022] The height of the medical heat lamp device and the arm guard device in this invention is adjusted by an automatic lifting mechanism, eliminating the need for manual adjustment, saving time and effort, and improving treatment efficiency; the angle and temperature of the medical heat lamp are also adjustable, which can meet the needs of different patients and treatment stages.
[0023] This invention is equipped with a temperature sensing patch and a control cabinet. The temperature sensing patch can collect data on the temperature of the patient's skin after it has been wrapped with sandpaper or plaster, allowing for the assessment of the patient's skin temperature. The control cabinet and temperature alarm provide an overheating alarm function. This enables data acquisition and intelligent alerts, reducing the workload of medical staff. The control cabinet contains a control module, and automated control significantly improves the equipment's usability. Patients can also control the height of the support rods and the angle of the protective plate to enhance comfort during treatment. Attached Figure Description
[0024] Figure 1 This is a schematic diagram of the overall structure of a medical scaffold device.
[0025] Figure 2 for Figure 1 A schematic diagram of the arm guard device.
[0026] Figure 3 This is a front view of a medical scaffold device.
[0027] Figure 4 for Figure 3 A schematic diagram of the medical heat lamp device.
[0028] Figure 5 This is a schematic diagram of the structure of a medical scaffold device after concealing the housing and temperature alarm. Detailed Implementation
[0029] The specific embodiments of this utility model will be further described below with reference to the accompanying drawings:
[0030] To facilitate postoperative wound healing and rehabilitation in patients' arms, and to provide comprehensive postoperative monitoring support for medical staff, this embodiment designs a medical arm scaffold device that integrates temperature monitoring, thermotherapy assistance, automated adjustment, and multi-angle support functions to optimize postoperative rehabilitation and improve patient comfort.
[0031] like Figure 1 As shown, a medical arm scaffold device includes a medical heat lamp device 1, an arm guard device 2, and a box base 3.
[0032] like Figure 2 As shown, the arm guard device 2 includes an upper arm guard 201, a forearm guard 202, a guard linkage mechanism 203, a cylindrical locking mechanism 204, and a motor 205. One end of the guard linkage mechanism 203 is connected to the cylindrical locking mechanism 204, and the other end is connected to the housing of the motor 205. Rods 2011 and 2012 are fixedly connected to both sides of the upper arm guard 201, and rods 2021 and 2022 are fixedly connected to both sides of the forearm guard 202. Rod 2011 on the upper arm guard 201 is connected to the housing of the motor 205. Rods 2012 on the upper arm guard 201 and 2022 on the forearm guard 202 are rotatably connected by a pin. Rod 2021 on the forearm guard 202 is connected to the output shaft of the motor 205. The motor 205 is a DC motor.
[0033] The angle between the upper arm guard 201 and the forearm guard 202 can be adjusted by motor 205. The position of the upper arm guard 201 is fixed. The output shaft of motor 205 drives the rotation of the forearm guard 202, thereby adjusting the angle between the upper arm guard 201 and the forearm guard 202. Motor 205 only drives the forearm guard 202 to rotate. The patient can adjust the angle via a remote control to increase comfort. The cylindrical locking mechanism 204 is locked onto the support rod 305 connected to the lifting rod of the automatic lifting mechanism 302 to the base of the housing 3.
[0034] like Figure 3 and Figure 4 As shown, the medical heating lamp device 1 includes a medical heating lamp 101, a heating lamp linkage mechanism 102, a temperature control switch 103, and a cylindrical locking mechanism 104. The medical heating lamp 101 is connected to one end of the heating lamp linkage mechanism 102, and the other end of the heating lamp linkage mechanism 102 is connected to the housing of the temperature control switch 103. The housing of the temperature control switch 103 is connected to the cylindrical locking mechanism 104.
[0035] The medical heat lamp 101 is installed at the end of the heat lamp linkage mechanism 102. The heat lamp linkage mechanism 102 enables multi-angle adjustment of the medical heat lamp 101. The heat lamp linkage mechanism 102 is connected to the housing of the temperature control switch 103, and the entire device is fixed to the support rod 305 connected to the lifting rod of the automatic lifting mechanism 302 of the housing base 3 by the cylindrical locking mechanism 104 on the housing of the temperature control switch 103. The temperature control switch 103 can adjust the temperature of the medical heat lamp 101 to meet the temperature requirements.
[0036] like Figure 1 and Figure 5 As shown, the base 3 includes a housing 301, an automatic lifting mechanism 302, a control cabinet 303, and a temperature alarm 304. The automatic lifting mechanism 302, control cabinet 303, and temperature alarm 304 are all connected to the housing 301. The temperature alarm 304 is located on the outer surface of the housing 301. A portion of the automatic lifting mechanism 302 and the control cabinet 303 are located inside the housing 301. The lifting rod of the automatic lifting mechanism 302 passes through a pre-drilled hole at the top of the housing 301, and its outer side is connected to a support rod 305. Both the first cylindrical locking mechanism 204 and the second cylindrical locking mechanism 104 are locked to the support rod 305, which is connected to the lifting rod of the automatic lifting mechanism 302. The temperature sensing patch and temperature control switch 103, used to collect the skin temperature of a patient's arm after it has been wrapped with sandpaper or plaster, are both connected to the control cabinet 303. The control cabinet 303 is connected to the temperature alarm 304, the automatic lifting mechanism 302, the medical heating lamp 101, and the motor 205. The temperature sensing patch, temperature control switch 103, control cabinet 303, temperature alarm 304, automatic lifting mechanism 302, medical heating lamp 101, and motor 205 are all connected to a power supply.
[0037] The automatic lifting mechanism 302 is a screw jack. The motor in the screw jack is a DC geared motor. The support rod 305 is connected to the lifting rod of the screw jack and is driven by the DC geared motor. The temperature alarm 304 can collect temperature signals through temperature sensing patches to monitor the patient's arm skin temperature in real time. The control cabinet 303 is used to house the control module of the whole device. The bottom of the cabinet 301 is equipped with casters 3011 for flexible movement of the equipment.
[0038] like Figure 2As shown, the guard plate linkage mechanism 203 includes a first linkage 2031 and a second linkage 2032. One end of the first linkage 2031 is connected to the housing of the first motor 205, and one end of the second linkage 2032 is connected to the first cylindrical locking mechanism 204. The other ends of the first linkage 2031 and the second linkage 2032 are locked together by a locking bolt 1030. When the nut at the rear end of the locking bolt 1030 is loosened, the angle between the first linkage 2031 and the second linkage 2032 can be adjusted. After the angle is adjusted to a suitable position, the nut at the rear end of the locking bolt 1030 can be tightened.
[0039] like Figure 4 As shown, the lamp linkage mechanism 102 includes a lower rod seat 1021, a middle rod seat 1022, an upper rod seat 1023, an upper lamp post 1024, an upper lamp post 2 1025, a lower lamp post 1026, a lower lamp post 2 1027, a lower cylinder support rod 1028, and an upper cylinder support rod 1029. The lower rod seat 1021 is fixedly connected to the top of the housing of the temperature control switch 103. The lower rod seat 1021 and the middle rod seat 1022 are rotatably connected through the lower lamp post 1026 and the lower lamp post 2 1027, and one end of the lower lamp post 1026 is locked to the middle rod seat 1022 by a locking bolt 1030. The middle rod seat 1022 and the upper rod seat 1023 are rotatably connected via upper lamp rod one 1024 and upper lamp rod two 1025. One end of upper lamp rod two 1025 is locked to the upper rod seat 1023 via a locking bolt 1030. One end of the lower cylinder support rod 1028 is rotatably connected to the lower rod seat 1021, and the other end is rotatably connected to the lower lamp rod one 1026. One end of the upper cylinder support rod 1029 is rotatably connected to the middle rod seat 1022, and the other end is rotatably connected to the upper lamp rod one 1024. The medical lamp 101 is locked to the upper rod seat via the locking bolt 1030. After the nuts at the rear ends of the locking bolts 1030 are loosened, rotation between the lower rod seat 1021 and the middle rod seat 1022, rotation between the middle rod seat 1022 and the upper rod seat 1023, and rotation between the medical lamp 101 and the upper rod seat can be achieved, thereby adjusting the position of the medical lamp 101.
[0040] The cylindrical locking mechanism 1 204 and the cylindrical locking mechanism 2 104 adopt a cylindrical clamp structure.
[0041] This embodiment also includes a remote control device, which is wirelessly connected to the control cabinet 303.
[0042] The temperature-sensing patch is applied to the skin of the patient's arm before the bandage or cast is applied. After treatment, the bandage or cast is removed first, followed by the temperature-sensing patch. Alternatively, if the patient's arm is already wrapped in bandage or cast, part of the bandage or cast can be removed, and the temperature-sensing patch can be inserted between the cast and the skin, or between the bandage and the skin. The temperature-sensing patch is a wired temperature-sensing patch.
[0043] The main process of this embodiment is as follows: First, a temperature-sensing patch is applied to the skin surface of the patient's arm after it is wrapped with sandpaper or plaster to monitor skin temperature. The entire device is powered on and initialized to ensure that the medical lamp 101, temperature control switch 103, control cabinet 303, and temperature-sensing patch are in working condition. The patient's arm is placed on the upper arm guard 201 and forearm guard 202. A signal is sent to the control cabinet 303 via a remote control device. The control cabinet 303 drives the motor 205 to rotate, thereby rotating the forearm guard 202 and adjusting the angle between the upper arm guard 201 and forearm guard 202 to ensure comfort. In addition, a signal is sent to the control cabinet 303 via a remote control device. The control cabinet 303 drives the motor in the automatic lifting mechanism 302 to rotate, thereby controlling the support rod 305 to move up and down, thereby adjusting the overall height of the arm guard device 2 and the medical lamp device 1 to meet the patient's comfort and medical operation needs. According to treatment needs, loosen the nut on the locking bolt 1030 on the guard plate linkage mechanism 203. The connecting rod 1 2031 and connecting rod 2032 of the guard plate linkage mechanism 203 can rotate, and the angle between connecting rod 1 2031 and connecting rod 2032 can be adjusted, thereby adjusting the overall angle of the upper arm guard plate 201 and the lower arm guard plate 202 to a suitable position. Loosen the nut on the locking bolt 1030 between one end of the lower lamp rod 1026 and the middle rod seat 1022 in the heat lamp linkage mechanism 102. Rotate the lower lamp rod 1026 and the lower lamp rod 2 1027 to adjust the position of the middle rod seat 1022. After adjustment, tighten the nut on the locking bolt 1030 to fix the position of the middle rod seat 1022. The lower cylinder support rod 1028 plays a supporting role. Loosen the nut on the locking bolt 1030 between one end of the upper lamp rod 1025 and the upper rod seat 1023 in the heat lamp linkage mechanism 102. Rotate the upper lamp rod 1024 and the upper lamp rod 1025 to adjust the position of the upper rod seat 1023. After adjustment, tighten the nut on the locking bolt 1030 to fix the position of the upper rod seat 1023. The upper cylinder support rod 1029 provides support. Loosen the nut on the locking bolt 1030 between the medical heat lamp 101 and the upper rod seat 1023 to adjust the angle between the medical heat lamp 101 and the upper rod seat. Tighten the locking bolt 1030 to fix the angle of the medical heat lamp 101.
[0044] In this embodiment, the medical lamp 101 can also be manually started and its temperature set via the temperature control switch 103 to provide heat therapy assistance. Specifically, pressing the temperature switch 103 sends a signal to the control cabinet 303, which then controls the medical lamp 101 to operate based on the signal. The temperature sensing patch collects the patient's skin temperature in real time. Based on the temperature data fed back by the temperature sensing patch, the control cabinet 303 can automatically adjust the power of the medical lamp 101 to maintain a suitable treatment temperature. If the temperature collected by the temperature sensing patch exceeds a set threshold, the control cabinet 303 triggers a temperature alarm 304 to remind medical staff to check the patient's condition based on the alarm information. After treatment, the equipment is turned off, the temperature sensing patch is removed, and the upper arm guard 201 and forearm guard 202 are adjusted to their original positions.
[0045] The scope of protection of this utility model includes, but is not limited to, the above embodiments. The scope of protection of this utility model is defined by the claims. Any substitutions, modifications, or improvements to this technology that are easily conceived by those skilled in the art shall fall within the scope of protection of this utility model.
Claims
1. A medical scaffold device, characterized in that, Includes a medical heat lamp device (1), an arm guard device (2), and a box base (3); The arm guard device (2) includes an upper arm guard (201), a forearm guard (202), a guard linkage mechanism (203), a cylindrical locking mechanism (204), and a motor (205); one end of the guard linkage mechanism (203) is connected to the cylindrical locking mechanism (204), and the other end is connected to the housing of the motor (205). The upper arm guard (201) is fixedly connected with a first rod (2011) and a second rod (2012), and the forearm guard (202) is connected to the housing of the motor (205). The boom guard plate (202) is fixedly connected with rod three (2021) and rod four (2022). Rod one (2011) on the boom guard plate (201) is connected to the housing of motor one (205). Rod two (2012) on the boom guard plate (201) and rod four (2022) on the forearm guard plate (202) are rotatably connected. Rod three (2021) on the forearm guard plate (202) is connected to the output end of motor one (205). The medical heating lamp device (1) includes a medical heating lamp (101), a heating lamp linkage mechanism (102), a temperature control switch (103), and a cylindrical locking mechanism (104). The medical heating lamp (101) is connected to one end of the heating lamp linkage mechanism (102), and the other end of the heating lamp linkage mechanism (102) is connected to the housing of the temperature control switch (103). The housing of the temperature control switch (103) is connected to the cylindrical locking mechanism (104). The base (3) of the box includes a box (301), an automatic lifting mechanism (302), a control cabinet (303) and a temperature alarm (304). The automatic lifting mechanism (302), the control cabinet (303) and the temperature alarm (304) are all connected to the box (301). The first cylindrical locking mechanism (204) and the second cylindrical locking mechanism (104) are locked to the lifting rod of the automatic lifting mechanism (302). The temperature sensing patch and the temperature control switch (103) used to collect the skin temperature of the patient's arm are connected to the control cabinet (303). The control cabinet (303) is connected to the temperature alarm (304), the automatic lifting mechanism (302), the first motor (205) and the medical heat lamp (101).
2. The medical scaffold device of claim 1, wherein, The guard plate linkage mechanism (203) includes a first linkage (2031) and a second linkage (2032). One end of the first linkage (2031) is connected to the housing of the first motor (205), and one end of the second linkage (2032) is connected to the first cylindrical locking mechanism (204). The other end of the first linkage (2031) and the other end of the second linkage (2032) are locked together by a rotary locking mechanism.
3. The medical scaffold device of claim 1, wherein, The lamp linkage mechanism (102) includes a lower rod seat (1021), a middle rod seat (1022), an upper rod seat (1023), an upper lamp rod one (1024), an upper lamp rod two (1025), a lower lamp rod one (1026), a lower lamp rod two (1027), a lower cylinder support rod (1028), and an upper cylinder support rod (1029). The lower rod seat (1021) is fixedly connected to the top of the housing of the temperature control switch (103). The lower rod seat (1021) and the middle rod seat (1022) are rotatably connected through the lower lamp rod one (1026) and the lower lamp rod two (1027), and one end of the lower lamp rod one (1026) is connected to the middle rod seat (1022) through... The rotating locking mechanism locks the connection. The middle rod seat (1022) and the upper rod seat (1023) are rotatably connected through the upper lamp rod one (1024) and the upper lamp rod two (1025). One end of the upper lamp rod two (1025) is locked to the upper rod seat (1023) through the rotating locking mechanism. One end of the lower cylinder support rod (1028) is rotatably connected to the lower rod seat (1021), and the other end is rotatably connected to the lower lamp rod one (1026). One end of the upper cylinder support rod (1029) is rotatably connected to the middle rod seat (1022), and the other end is rotatably connected to the upper lamp rod one (1024). The medical heating lamp (101) is locked to the upper rod seat through the rotating locking mechanism.
4. The medical scaffold device of claim 1, wherein, Both the first cylindrical locking mechanism (204) and the second cylindrical locking mechanism (104) are locked to the support rod (305), and the support rod (305) is connected to the lifting rod of the automatic lifting mechanism (302).
5. The medical scaffold device of claim 4, wherein, The automatic lifting mechanism (302) is a screw jack.
6. The medical scaffold device of claim 1, wherein, The first cylindrical locking mechanism (204) and the second cylindrical locking mechanism (104) adopt cylindrical clamps.
7. The medical scaffold device of claim 1, wherein, The bottom of the housing (301) is provided with casters (3011).
8. The medical scaffold device of claim 1, wherein, It also includes a remote control device, which is wirelessly connected to the control cabinet (303).
9. The medical scaffold device of claim 2 or 3, wherein, The rotary locking mechanism uses a locking bolt (1030).