Medical instrument transfer device

Abstract

The utility model relates to medical instrument transfer technical field, and disclose a kind of medical instrument transfer device, including trolley, loading assembly includes the loading box being arranged in support frame inside, loading box outer wall is equipped with magnet plate, support frame inner wall is equipped with multiple connecting seats, multiple connecting seat inside are equipped with connecting rod, connecting rod one end is equipped with piston, other end is equipped with adhering plate;Connecting seat inner wall is equipped with through slot, through slot other end is equipped with cavity, cavity inside is equipped with spring and conducting block, support frame inner wall is equipped with multiple electromagnet, multiple electromagnet outside are equipped with wire head.The utility model improves the protection performance to medical instrument by the double-layer structure of support frame and loading box, and make loading box hang in support frame by air pressure, reduce the conduction of vibration in the process of transfer, while cooperate the magnetic force generated by electromagnet in support frame, auxiliary support loading box to avoid the contact between loading box and support frame, improve the stability of loading box, and avoid to cause knock break to internal medical instrument.

Description

Technical Field

[0001] This utility model relates to the field of medical device transport technology, specifically a medical device transport device. Background Technology

[0002] Medical device transport devices are used to safely and efficiently move and transport medical devices or patients in medical settings. They play an indispensable role in the medical field, and their diverse and specialized designs and functions ensure the safety and efficiency of patients and medical devices during transport. With continuous technological advancements, these devices will evolve towards intelligence, automation, and multifunctionality, providing stronger support for healthcare services.

[0003] During the movement of the transfer device, when the wheels encounter uneven ground, the frame will vibrate. Since medical devices are usually quite precise, the vibration can easily cause the internal parts of the medical devices to loosen when it is transmitted. The vibration may also cause the devices to collide with the storage frame and be damaged, affecting the accuracy of the equipment or causing damage to the equipment. Utility Model Content

[0004] The purpose of this utility model is to provide a medical device transport device to solve the problem mentioned in the background art that during the transport process, bumps caused by the road surface or wheels will cause vibration of the transport device, which will cause the internal medical device components to loosen or be damaged by collision with the box.

[0005] To achieve the above objectives, the present invention provides the following technical solution: a medical device transport device, comprising a trolley, wheels at the bottom of the trolley, a support frame at the top of the trolley, a loading assembly for storing medical devices inside the support frame, the loading assembly including a loading box inside the support frame, a magnetic plate on the outer wall of the loading box, and multiple connecting seats on the inner wall of the support frame, each of the multiple connecting seats having a connecting rod inside, a piston at one end of the connecting rod, and a bonding plate at the other end;

[0006] The inner wall of the connector is provided with a through groove, and the other end of the through groove is provided with a cavity. A spring and a conductive block are provided inside the cavity. Multiple electromagnets are provided on the inner wall of the support frame, and each of the multiple electromagnets has a wire end on its outside.

[0007] Preferably, the wheels are rotatably connected to the bottom of the trolley via a fixed axle, and the wheels are covered with shock-absorbing pads. The support frame is connected to the internal load-bearing plate of the trolley via bolts. The support frame is a hollow structure, and the loading box is located inside the support frame.

[0008] Preferably, a plurality of the connecting seats are distributed around the inner wall of the support frame, the connecting seats are filled with high-pressure gas, one end of the connecting rod is located inside the connecting seat and is slidably connected to the inner wall of the connecting seat, and is connected to the piston.

[0009] Preferably, the other end of the connecting rod extends into the support frame and is connected to the bonding plate, which abuts against and fits against the outer wall of the loading box inside the support frame.

[0010] Preferably, the two ends of the through groove are connected to the connecting seat and the cavity respectively, the conductive block is located in the cavity and is slidably connected to the inner wall of the cavity, and the two ends of the spring are connected to the inner wall of the cavity and the conductive block respectively.

[0011] Preferably, the plurality of conductive blocks are respectively embedded and connected to the inner walls of the support frame, and their distribution angle corresponds to the magnetic plate outside the loading box. One end of the wire head is embedded in the cavity, and the other end is connected to the electromagnet through a wire.

[0012] Compared with the prior art, the beneficial effects of this utility model are:

[0013] 1. The shock-absorbing pads on the wheels reduce the amplitude of bumps when encountering uneven road surfaces. The double-layer structure of the support frame and loading box improves the protection of the medical devices inside the loading box. Furthermore, the connecting seat inside the support frame and the high-pressure gas inside the connecting seat, together with the connecting rod and the bonding plate, abut against the loading box, thus supporting the loading box and keeping it suspended within the support frame. This reduces the transmission of vibrations during trolley movement, thereby improving the stability of the loading box and the medical devices inside.

[0014] 2. By reserving a through slot in the connecting seat, gas can be transported into the cavity. When the loading box shakes, it pushes the connecting rod to retract into the connecting seat, compressing the gas inside and increasing the air pressure in the connecting seat and cavity. The air pressure, combined with the bonding plate, supports the loading box. At the same time, the air pressure in the cavity pushes the conductive block to one side, making it fit with the lead wire and power supply end of the electromagnet. This activates the electromagnet, causing it to generate magnetic force. This force, combined with the magnetic plate outside the loading box, provides auxiliary support to the loading box through the magnetic poles. The loading box is thus suspended in the support frame by magnetic force, effectively avoiding friction and collision between the loading box and the support frame, and further improving the stability of the loading box.

[0015] This invention improves the protection of medical devices through a double-layer structure of a support frame and a loading box. The loading box is suspended in the support frame by air pressure, which reduces the transmission of vibration during transportation. At the same time, the magnetic force generated by the electromagnet in the support frame assists in supporting the loading box and avoids contact between the loading box and the support frame, thereby improving the stability of the loading box and preventing damage to the internal medical devices. Attached Figure Description

[0016] Figure 1 This is an overall isometric view of the present invention;

[0017] Figure 2 This is a structural diagram of the support frame and loading box of this utility model.

[0018] Figure 3 This is an internal sectional view of the support frame of this utility model;

[0019] Figure 4 This is an enlarged view of part A of this utility model.

[0020] In the diagram: 1. Trolley; 2. Wheel; 3. Support frame; 4. Loading box; 401. Magnetic plate; 5. Connecting seat; 501. Connecting rod; 502. Piston; 6. Adhesive plate; 7. Through groove; 8. Cavity; 801. Spring; 802. Conductive block; 9. Electromagnet; 901. Wire end. Detailed Implementation

[0021] 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.

[0022] All devices in this application adopt conventional models in the prior art, and the control method is through a controller. The control circuit of the controller can be implemented by simple programming by those skilled in the art, which is common knowledge in the field, so this application will not explain it in detail.

[0023] Please see the appendix Figures 1-3As shown, a medical device transport device includes a trolley 1 with wheels 2 at the bottom. Shock-absorbing pads covering the wheels 2 reduce bumps caused by uneven roads. A support frame 3 is located on top of the trolley 1, serving as an outer structure to enclose a loading box 4, improving the protection of the medical device. Inside the support frame 3 is a loading assembly for storing the medical device. The loading assembly includes a loading box 4 housed within the support frame 3, used for loading the medical device. The inner wall of the loading box 4 is lined with foam padding to prevent impact to the medical device. The outer wall of the loading box 4 is... A magnetic plate 401 is provided, and multiple connecting seats 5 are provided on the inner wall of the support frame 3 for angular positioning of the connecting rod 501 and the bonding plate 6. Each of the multiple connecting seats 5 is provided with a connecting rod 501. The two ends of the connecting rod 501 are connected to the piston 502 and the bonding plate 6 respectively, so that they are linked. One end of the connecting rod 501 is provided with the piston 502, and the other end is provided with the bonding plate 6. The high pressure of the gas in the connecting seat 5 supports the piston 502 and the connecting rod 501, thereby pushing the bonding plate 6 to abut against the outer wall of the loading box 4 in the support frame 3. The resistance generated by the gas pressure in the connecting seat 5 supports the loading box 4.

[0024] Wheel 2 is rotatably connected to the bottom of trolley 1 via a fixed axle, and shock-absorbing pads are wrapped around the outside of wheel 2. Support frame 3 is connected to the internal bearing plate of trolley 1 via bolts. Support frame 3 is a hollow structure, and loading box 4 is located inside support frame 3. Multiple connecting seats 5 are distributed around the inner wall of support frame 3. High-pressure gas is loaded inside the connecting seats 5. One end of connecting rod 501 is located inside connecting seat 5 and is slidably connected to the inner wall of connecting seat 5 and connected to piston 502. The other end of connecting rod 501 extends into support frame 3 and is connected to bonding plate 6. Bonding plate 6 abuts against the outer wall of loading box 4 inside support frame 3.

[0025] In this embodiment: During use, the medical device is placed inside the loading box 4. At the same time, the gas in the connecting seat 5 inside the support frame 3 pushes the connecting rod 501 and piston 502 to extend outward from the connecting seat 5, and pushes the bonding plate 6 to abut against the loading box 4, continuously providing support force to the loading box 4, so that the loading box 4 is suspended inside the support frame 3, avoiding friction or collision between the loading box 4 and the inner wall of the support frame 3. At the same time, when the trolley 1 and the support frame 3 shake during transportation, the suspension of the loading box 4 isolates and buffers the vibration force, reduces the transmission of vibration, improves the stability of the loading box 4, and reduces the impact of vibration or bumps on the medical device inside the loading box 4.

[0026] Example 2: This example is an improvement on Example 1. For details, please refer to [link / reference]. Figures 3-4The inner wall of the connecting seat 5 is provided with a through groove 7, which allows the connecting seat 5 to communicate with the cavity 8, and the gas in the connecting seat 5 can be transported into the cavity 8. The other end of the through groove 7 is provided with a cavity 8. A spring 801 and a conductive block 802 are provided inside the cavity 8. The spring 801 is used to pull the conductive block 802, so that in the normal state, the conductive block 802 is located at one end of the cavity 8 away from the wire head 901 and the power supply end. The inner wall of the support frame 3 is provided with multiple electromagnets 9. After being energized, the electromagnets 9 generate magnetic poles and repel the magnetic plate 401 outside the loading box 4. The repulsive force of the magnetic poles supports the loading box 4, avoiding frictional contact between the loading box 4 and the inner wall of the support frame 3. Wire heads 901 are provided on the outside of each of the multiple electromagnets 9.

[0027] The two ends of the through groove 7 are connected to the connecting seat 5 and the cavity 8 respectively. The conductive block 802 is located in the cavity 8 and is slidably connected to the inner wall of the cavity 8. The two ends of the spring 801 are connected to the inner wall of the cavity 8 and the conductive block 802 respectively. Multiple conductive blocks 802 are embedded and connected to the inner walls of the support frame 3 respectively, and their distribution angle corresponds to the magnetic plate 401 outside the loading box 4. One end of the wire head 901 is embedded in the cavity 8, and the other end is connected to the electromagnet 9 through the wire.

[0028] In this embodiment: when the bumps generated by the trolley 1 and the support frame 3 cause the loading box 4 to move within the support frame 3, the movement of the loading box 4 will simultaneously squeeze the bonding plate 6 on the inner wall of the support frame 3, thereby pushing the connecting rod 501 on the other side of the bonding plate 6 to retract into the connecting seat 5 and cooperate with the piston 502 to squeeze the gas in the connecting seat 5. The resistance of the air pressure supports and buffers the loading box 4. At the same time, the compressed gas will be transported into the cavity 8 through the through groove 7, increasing the air pressure in the cavity 8. The air pressure pushes the conductive block 802 to move to the other end of the cavity 8 and place it between the wire head 901 and the power supply end and fit it. The conductive block 802 transmits the current from the power supply end to the wire head 901 to power the electromagnet 9, activating it and generating magnetic poles that repel the magnetic plate 401 outside the loading box 4. The magnetic poles assist in supporting the loading box 4, further avoiding collision between the loading box 4 and the inner wall of the support frame 3, and improving the stability of the loading box 4.

[0029] The contents not described in detail in this specification are existing technologies known to those skilled in the art.

[0030] Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.

Claims

1. A medical instrument transfer device, comprising a trolley (1), the bottom of the trolley (1) is provided with wheels (2), the top of the trolley (1) is provided with a support frame (3), the inside of the support frame (3) is provided with a loading assembly for storing medical instruments, characterized in that: The loading assembly includes a loading box (4) disposed inside the support frame (3). The outer wall of the loading box (4) is provided with a magnetic plate (401). The inner wall of the support frame (3) is provided with multiple connecting seats (5). Each of the multiple connecting seats (5) is provided with a connecting rod (501). One end of the connecting rod (501) is provided with a piston (502), and the other end is provided with a bonding plate (6). The inner wall of the connecting seat (5) is provided with a through groove (7), and the other end of the through groove (7) is provided with a cavity (8). A spring (801) and a conductive block (802) are provided inside the cavity (8). A plurality of electromagnets (9) are provided on the inner wall of the support frame (3), and each of the plurality of electromagnets (9) is provided with a wire head (901) on the outside.

2. The medical device transport device according to claim 1, characterized in that: The wheel (2) is rotatably connected to the bottom of the cart (1) via a fixed shaft, and the wheel (2) is wrapped with a shock-absorbing pad. The support frame (3) is connected to the internal bearing plate of the cart (1) via bolts. The support frame (3) is a hollow structure, and the loading box (4) is located inside the support frame (3).

3. The medical device transport device according to claim 1, characterized in that: Multiple connecting seats (5) are distributed around the inner wall of the support frame (3). The connecting seats (5) are filled with high-pressure gas. One end of the connecting rod (501) is located inside the connecting seat (5) and is slidably connected to the inner wall of the connecting seat (5) and connected to the piston (502).

4. A medical device transport device according to claim 3, characterized in that: The other end of the connecting rod (501) extends into the support frame (3) and is connected to the bonding plate (6), which abuts against the outer wall of the loading box (4) inside the support frame (3).

5. A medical device transport device according to claim 1, characterized in that: The two ends of the through groove (7) are connected to the connecting seat (5) and the cavity (8) respectively. The conductive block (802) is located in the cavity (8) and is slidably connected to the inner wall of the cavity (8). The two ends of the spring (801) are connected to the inner wall of the cavity (8) and the conductive block (802) respectively.

6. A medical device transport device according to claim 5, characterized in that: Multiple conductive blocks (802) are respectively embedded and connected to the inner walls of the support frame (3), and their distribution angle corresponds to the magnetic plate (401) outside the loading box (4). One end of the wire head (901) is embedded in the cavity (8), and the other end is connected to the electromagnet (9) through the wire.

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