A container-integrated operating room
By dividing the container operating room into a disinfection room, a storage room, and an operating room, and equipping it with an automatic disinfection mechanism, the problem of external dust and virus adhesion is solved, enabling medical staff to disinfect themselves and patients to be transferred conveniently, thus improving disinfection efficiency and environmental cleanliness.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- 湖南捷工医疗科技有限公司
- Filing Date
- 2023-12-07
- Publication Date
- 2026-07-03
Smart Images

Figure CN117822950B_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of medical device technology, and in particular to a container-integrated operating room. Background Technology
[0002] With the development of medical rescue equipment, expandable surgical cabins such as vehicle-mounted and ship-mounted ones have emerged. Operating rooms with this structure can maintain a clean internal environment and can be deployed to the front line of disaster relief to provide timely, rapid and high-level medical assistance.
[0003] A search revealed that utility model CN214576061U discloses an emergency hybrid operating room, including a container. The operating room body is located at the right end of the container's inner cavity. This utility model solves the problem of current emergency hybrid operating rooms being large in size and requiring a large amount of manpower or large vehicles for movement by using a combination of rotating wheels, a first electric telescopic rod, a first fixed plate, a long pipe, a pump, a second fixed plate, a second electric telescopic rod, a movable plate, moving wheels, a disinfectant storage tank, a liquid level sensor, a first motor, a second motor, a first gear disk, a second gear disk, a rotating shaft, and a water tap.
[0004] The operating room also has the following disadvantages during use: When used outdoors, dust and viruses from outside stick to clothing and skin when entering and exiting the operating room, requiring dedicated personnel to stand at the door for disinfection, or medical staff to disinfect each other, which wastes manpower. In addition, the container door is small, making it inconvenient to transfer patients. Summary of the Invention
[0005] The purpose of this invention is to address the shortcomings of existing technologies, such as dust and viruses from outside sticking to clothing and skin when entering and exiting the operating room, requiring dedicated personnel to stand at the door for disinfection or medical staff to disinfect each other, which wastes manpower, and the small doors of the containers making it inconvenient to transfer patients. Therefore, this invention proposes an integrated container operating room.
[0006] To achieve the above objectives, the present invention adopts the following technical solution:
[0007] An integrated container operating room includes a container, one end of which is closed and the other end is rotatably equipped with two second doors. Two partitions are fixedly installed inside the container, and the two partitions and the second doors divide the container into an operating room for performing surgery, a storage room for holding medical equipment, and a disinfection room for disinfecting medical staff.
[0008] The container has a first door on one side that is rotatably connected to the disinfection room, and the partition has a fourth door on one side that is rotatably connected to seal the space between the disinfection room, the storage room and the operating room.
[0009] The first disinfection unit, located in the disinfection room, is used to remove dust and disinfect the surface of medical staff's bodies, as well as clean and disinfect the soles of their feet.
[0010] The second disinfection mechanism is located in the operating room and is used to disinfect the operating room. It can also automatically open and close the second door.
[0011] The top of the container is equipped with a gas chamber for supplying air to the operating room, and a power distribution cabinet connected to an external power source for supplying power to the equipment inside the container.
[0012] In one possible design, the first disinfection mechanism includes a disinfection table disposed within a disinfection chamber, the disinfection table being fixedly disposed on the bottom inner wall of the container, a water collection tray being fixedly disposed on one side of the disinfection table, a guide rod being fixedly disposed between the water collection tray and the container, a first screw being rotatably disposed through the top of the container, a reciprocating screw being fixedly disposed at the bottom of the first screw, the bottom of the reciprocating screw being rotatably connected to the water collection tray, a dust suction ring being threadedly sleeved on the outer wall of the first screw, one side of the dust suction ring being slidably sleeved on the guide rod, a second motor being fixedly disposed on the top of the container, the output end of the second motor being fixedly connected to the first screw, a vacuum cleaner being fixedly disposed on the top of the container, the air inlet end of the vacuum cleaner being connected to the dust suction ring through a first spring tube, a pedal being threadedly sleeved on the outer wall of the reciprocating screw, one side of the pedal being slidably sleeved on the guide rod.
[0013] In one possible design, a water spray ring is fixedly provided at the bottom of the dust suction ring, a sliding rod is fixedly provided on one side of the water spray ring, the top of the sliding rod is slidably connected to the top of the container, a first water tank is fixedly provided at the top of the container, a first sliding tube is slidably provided through the top of the first water tank, the first sliding tube and the sliding rod are fixedly connected by a connecting plate, a connecting tube is fixedly provided at the top of the first sliding tube, the other end of the connecting tube extends into the container, the water spray ring and the connecting tube are connected by a second spring tube, and a first rubber cylinder is fixedly provided at the bottom of the first sliding tube.
[0014] In one possible design, the water collection tray contains a third water tank, and the top of the third water tank is slidably provided with multiple second sliding tubes. The bottom end of the second sliding tube is fixedly provided with a second rubber cylinder, and the outer wall of the second sliding tube is fitted with a return spring. The two ends of the return spring are respectively fixedly connected to the side of the third water tank and the second rubber cylinder that are close to each other. The top of the pedal is provided with a through hole corresponding to the second sliding tube.
[0015] In one possible design, the second disinfection mechanism includes a connecting frame located in the operating room, the connecting frame being fixed to the inner wall of the container, a strip-shaped nozzle slidingly disposed on the inner wall of the connecting frame, an externally threaded tube penetrating one side of the connecting frame, one end of the externally threaded tube communicating with the strip-shaped nozzle, and an L-shaped sliding tube fixedly disposed at the other end of the externally threaded tube, a second water tank being fixedly disposed on the top of the container, a connecting cylinder being fixedly disposed on the inner wall of the second water tank, the L-shaped sliding tube penetrating and slidingly disposed on one side of the second water tank and located inside the connecting cylinder, a piston ring slidingly disposed on the inner wall of the connecting cylinder, the piston ring being fixedly sleeved on the L-shaped sliding tube, and two water holes being formed on the outer wall of the connecting cylinder.
[0016] In one possible design, a nut ring is rotatably provided through one side of the connecting frame, a first motor is fixedly provided on the top of the container, and meshing gears are fixedly fitted on the output end of the first motor and the outer wall of the nut ring, and the nut ring is threaded onto an external threaded pipe.
[0017] In one possible design, a baffle is fixedly fitted on the outer wall of the externally threaded tube, and two telescopic rods are rotatably provided at the bottom of the baffle. The other end of the telescopic rods is rotatably connected to the corresponding second door body, and a groove corresponding to the gear is opened on one side of the baffle.
[0018] In one possible design, the top of the second sliding tube has multiple rectangular openings.
[0019] In one possible design, a pad is provided on one side of the container, and the pad is located on one side of the second door.
[0020] In one possible design, a shoe sole disinfection device is installed at the pedal. The shoe sole disinfection device includes a water collection pool. Multiple motor-driven water spray pipes are rotatably mounted on the upper part of the water collection pool via bearings. The water spray pipes are arranged with a concave arc surface. Spiral reinforcing ribs are evenly distributed on the outer surface of the water spray pipes. Water spray nozzles are opened on the water spray pipes and are located at the intervals of the spiral reinforcing ribs. A trigger mechanism is inserted into the water spray nozzle. The trigger mechanism includes a polygonal connecting post in the middle of the bottom inverted buckle and an end head at the top. The connecting post is adapted to the water spray nozzle and has a water passage groove on the connecting post.
[0021] In this application, the device is first moved to the place of use. The patient is pushed into the operating room through one side of the container, while medical staff enter the sterilization room and stand on the sterilization table. Then, the second motor is started to rotate forward, driving the first screw to rotate. This causes the dust suction ring and water spray ring to move upward. At the same time, the vacuum cleaner is started, using the dust suction ring to suck up dust from the clothing. Simultaneously, the sliding rod drives the first sliding tube to move upward, so that the bottom of the first rubber cylinder is away from the bottom inner wall of the first water tank. At this time, water from the first water tank will enter the first rubber cylinder. The rotation of the first screw will drive the reciprocating screw to rotate. The rotation of the reciprocating screw can actuate the pedal to move downward, allowing the second sliding tube to be inserted into the pedal. Continuing to move downward, the second sliding tube can be moved downward by the sole of the shoe. The first motor moves downwards, causing the second rubber cylinder to move. When the bottom of the second rubber cylinder contacts the bottom of the third water tank, it continues to move downwards, squeezing the second rubber cylinder. This forces the water inside the second rubber cylinder upwards through the second sliding tube to clean the sole of the shoe. Then, the second motor is started to rotate in the opposite direction, causing the dust suction ring and water spray ring to move downwards through the first screw. At the same time, the first sliding tube moves downwards through the sliding rod. When the first rubber cylinder contacts the bottom inner wall of the first water tank, it continues to move downwards, squeezing the first rubber cylinder. This forces the disinfectant inside the first rubber cylinder to be sprayed through the connecting pipe and the second spring tube from the water spray ring to disinfect the medical staff. The second motor is then started to rotate forward, causing the guide rod to move downwards, allowing the medical staff to get off the pedal.
[0022] Then, the patient is taken from the storage room into the operating room, placed on the operating table, and then the bed is pushed out of the operating room.
[0023] Secondly, starting the first motor drives the gear to rotate, which in turn drives the nut ring to rotate. During the rotation, the external threaded tube moves, and the piston ring squeezes the water in the connecting cylinder while moving. This causes the water to pass through the L-shaped sliding tube and the external threaded tube and be sprayed out from the strip nozzle, thus disinfecting the operating room while moving.
[0024] At the same time, the telescopic rods close the two second doors, sealing the operating room.
[0025] In this invention, the container-integrated operating room can disinfect medical personnel entering the disinfection room through a first disinfection mechanism, eliminating the need for individual disinfection and mutual disinfection among medical personnel, thus saving energy and making it convenient to use.
[0026] In this invention, the container-integrated operating room can be disinfected in all directions within the operating room through a second disinfection mechanism, and the second door can be closed at the same time, which not only facilitates the patient's entry into the operating room, but also eliminates the need to manually close the second door;
[0027] In this invention, the container-integrated operating room, through a second disinfection mechanism, divides the interior of the container into a disinfection room, a storage room, and an operating room, and seals them together, which can effectively maintain the cleanliness of the surgical environment, and can store a certain amount of medical tools and consumables in the storage room.
[0028] In this invention, by activating the second motor, not only can dust be cleaned from the medical staff, but it can also be disinfected. During the disinfection process, the soles of their feet can also be cleaned and disinfected, improving the disinfection effect. At the same time, when the second motor is activated, it can not only drive the second door to open and close, but also drive the strip nozzle to move in the operating room to disinfect the operating room. It is convenient to use and does not require special personnel for disinfection and cleaning.
[0029] In this invention, water is sprayed only when the trigger comes into contact with the sole of the shoe, and there are no dead corners in contact, so the sole of the shoe can be completely disinfected. The angle of the water spray changes with the rotation of the water spray pipe, which can improve the rinsing effect. In addition, the spiral reinforcing ribs can scrape off stubborn dirt, which can improve the disinfection effect. Attached Figure Description
[0030] Figure 1 This is a three-dimensional structural diagram of an integrated container operating room proposed in this invention;
[0031] Figure 2 This is a three-dimensional structural diagram of an integrated container operating room proposed in this invention from another perspective;
[0032] Figure 3 This is a schematic diagram of the container-integrated operating room proposed in this invention, with the container removed.
[0033] Figure 4 This is a schematic diagram of the sterilization table structure of an integrated container operating room proposed in this invention;
[0034] Figure 5 This is a schematic cross-sectional view of the first water tank of an integrated container operating room proposed in this invention.
[0035] Figure 6 for Figure 4 Another perspective structural diagram;
[0036] Figure 7 This is a cross-sectional schematic diagram of the third water tank structure of an integrated container operating room proposed in this invention;
[0037] Figure 8 This is a schematic diagram of the external threaded pipe structure of an integrated container operating room proposed in this invention;
[0038] Figure 9 for Figure 8Another perspective structural diagram;
[0039] Figure 10 This is a cross-sectional schematic diagram of the second water tank structure of an integrated container operating room proposed in this invention.
[0040] In the diagram: 1. Container; 2. First door; 3. Second door; 4. Pad strip; 5. First water tank; 6. Power distribution cabinet; 7. Second water tank; 8. Gas tank; 9. First motor; 11. Second motor; 12. Vacuum cleaner; 14. Connecting frame; 15. Operating room; 16. Strip nozzle; 17. Storage room; 18. Partition; 19. Fourth door; 20. Disinfection table; 21. Disinfection chamber; 22. Water collection tray; 23. Guide rod; 24. First screw; 25. First spring tube; 26. Second spring tube; 27. Dust suction ring; 28. Water spray ring; 29. Sliding rod; 30. First sliding... 31. Moving pipe; 32. Connecting plate; 33. Connecting pipe; 34. First rubber cylinder; 35. Reciprocating screw; 36. Pedal; 37. Third water tank; 38. Second sliding pipe; 39. Rectangular opening; 40. Second rubber cylinder; 41. Return spring; 42. External threaded pipe; 43. L-shaped sliding pipe; 44. Gear; 45. Baffle; 46. Nut ring; 47. Telescopic rod; 48. Connecting cylinder; 49. Water hole; 50. Piston ring; 51. Water collection tank; 52. Spray pipe; 53. Spiral reinforcing rib; 54. End; 55. Water channel; 56. Connecting column; 57. Spray nozzle; 58. Inverted buckle. Detailed Implementation
[0041] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments.
[0042] Example 1
[0043] Reference Figures 1-10 A container-integrated operating room, which is used in the field of medical device technology, includes: a container 1, one end of the container 1 is closed, and the other end is rotatably provided with two second doors 3. Two partitions 18 are fixedly provided inside the container 1. The two partitions 18 and the second doors 3 divide the container 1 into an operating room 15 for performing surgery, a storage room 17 for holding medical equipment, and a disinfection room 21 for disinfecting medical staff.
[0044] A first door 2 corresponding to the disinfection chamber 21 is rotatably provided on one side of the container 1, and a fourth door 19 is rotatably provided on one side of the partition 18 for sealing the space between the disinfection chamber 21, the storage room 17 and the operating room 15.
[0045] The first disinfection unit, located in disinfection room 21, is used to remove dust and disinfect the surface of medical staff's bodies, and at the same time clean and disinfect the soles of medical staff's feet;
[0046] The second disinfection mechanism is set up in the operating room 15 to disinfect the operating room 15, and can also automatically open and close the second door 3.
[0047] The top of container 1 is equipped with a gas box 8 for supplying air to the operating room 15. The top of container 1 is also equipped with a power distribution cabinet 6 connected to an external power source for supplying power to the equipment inside container 1. The disinfection room 21, storage room 17, and operating room 15 facilitate the disinfection of medical personnel, storage of medical equipment, and the performance of surgeries. Furthermore, the first and second disinfection mechanisms can simultaneously disinfect medical personnel and operating room 15, eliminating the need for dedicated personnel for disinfection. It is also easy to move to different locations for temporary use, providing convenience for rescue operations.
[0048] The first disinfection mechanism includes a disinfection table 20 installed in a disinfection chamber 21. The disinfection table 20 is fixedly installed on the bottom inner wall of the container 1. A water collection tray 22 is fixedly installed on one side of the disinfection table 20. A guide rod 23 is fixedly installed between the water collection tray 22 and the container 1. A first screw 24 is rotatably installed through the top of the container 1. A reciprocating screw 34 is fixedly installed at the bottom of the first screw 24. The bottom of the reciprocating screw 34 is rotatably connected to the water collection tray 22. A dust suction ring 27 is threaded onto the outer wall of the first screw 24. One side of the dust suction ring 27 is slidably fitted onto the guide rod 23. A second motor 11 is fixedly installed on the top of the container 1. The output end of the second motor 11... A vacuum cleaner 12 is fixedly connected to the first screw 24 and fixedly installed on the top of the container 1. The air inlet of the vacuum cleaner 12 is connected to the suction ring 27 through the first spring tube 25. A pedal 35 is threaded on the outer wall of the reciprocating screw 34. One side of the pedal 35 is slidably sleeved on the guide rod 23. By starting the second motor 11, the first screw 24 can be driven to rotate. The rotation of the first screw 24 can drive the suction ring 27 to move up and down. During the movement, the vacuum cleaner 12 can clean the dust on the surface of the medical staff's body. At the same time, it drives the reciprocating screw 34 to rotate, which can drive the pedal 35 to move up and down, so that it can clean the medical staff from all directions.
[0049] A water spray ring 28 is fixedly installed at the bottom of the dust suction ring 27. A sliding rod 29 is fixedly installed on one side of the water spray ring 28. The top of the sliding rod 29 is slidably connected to the top of the container 1. A first water tank 5 is fixedly installed on the top of the first water tank 5. A first sliding tube 30 is slidably installed through the top of the first water tank 5. The first sliding tube 30 and the sliding rod 29 are fixedly connected by a connecting plate 31. A connecting tube 32 is fixedly installed at the top of the first sliding tube 30. The other end of the connecting tube 32 extends into the container 1. The water spray ring 28 and the connecting tube 32... The two are connected by a second spring tube 26. The bottom end of the first sliding tube 30 is fixedly provided with a first rubber cylinder 33. When the dust suction ring 27 drives the water spray ring 28 to move downward, it can drive the first sliding tube 30 to move downward through the sliding rod 29 and the connecting plate 31. When the first rubber cylinder 33 contacts the bottom of the first water tank 5, the first rubber cylinder 33 is squeezed. The water in the first rubber cylinder 33 can be sprayed onto the medical staff through the connecting tube 32, the second spring tube 26 and the water spray ring 28, so as to disinfect the medical staff in all directions.
[0050] The water collection tray 22 contains a third water tank 36. Multiple second sliding tubes 37 are slidably mounted through the top of the third water tank 36. A second rubber cylinder 39 is fixedly mounted at the bottom of the second sliding tube 37. A return spring 40 is sleeved on the outer wall of the second sliding tube 37. The two ends of the return spring 40 are fixedly connected to the adjacent sides of the third water tank 36 and the second rubber cylinder 39, respectively. The top of the pedal 35 has a through hole corresponding to the second sliding tube 37. When medical staff stand on the pedal 35 and move downwards, the second sliding tube 37 can be moved and inserted into the through hole. Continuing to move downwards, the second sliding tube 37 can be moved downwards by the foot. When the second rubber cylinder 39 contacts the bottom of the third water tank 36, continuing to move can cause the water in the second rubber cylinder 39 to move upwards and spray out from the second sliding tube 37 to disinfect and clean the soles of the feet.
[0051] The second disinfection mechanism includes a connecting frame 14 located within the operating room 15. The connecting frame 14 is fixed to the inner wall of the container 1. A strip-shaped nozzle 16 is slidably mounted on the inner wall of the connecting frame 14. An externally threaded pipe 41 passes through one side of the connecting frame 14, with one end of the externally threaded pipe 41 communicating with the strip-shaped nozzle 16. An L-shaped sliding pipe 42 is fixedly mounted on the other end of the externally threaded pipe 41. A second water tank 7 is fixedly mounted on the top of the container 1. A connecting cylinder 47 is fixedly mounted on the inner wall of the second water tank 7. The L-shaped sliding pipe 42 passes through and slides along one side of the second water tank 7 and is located inside the connecting cylinder 47. A piston ring 49 is slidably mounted on the inner wall of the connecting cylinder 47 and is fixedly fitted onto the L-shaped sliding pipe 42. The outer wall of the connecting cylinder 47 has two water holes 48. Pushing the L-shaped sliding tube 42 and driving the external threaded tube 41 can move the strip nozzle 16 within the connecting frame 14, while simultaneously driving the piston ring 49 to slide within the connecting cylinder 47, squeezing the water in the connecting cylinder 47 into the L-shaped sliding tube 42, and then spraying it into the operating room 15 through the external threaded tube 41 and the strip nozzle 16, disinfecting the operating room 15 while moving. Conversely, pulling the L-shaped sliding tube 42 and driving the external threaded tube 41 can move the piston ring 49 within the connecting cylinder 47. When the piston ring 49 moves to one side of the water hole 48, the water in the second water tank 7 will enter the connecting cylinder 47 through the water hole 48.
[0052] A nut ring 45 is rotatably mounted through one side of the connecting frame 14. A first motor 9 is fixedly mounted on the top of the container 1. A meshing gear 43 is fixedly mounted on the output end of the first motor 9 and the outer wall of the nut ring 45. The nut ring 45 is threaded onto the external threaded tube 41. The nut ring 45 can be rotated by the gear 43 driven by the connecting frame 14. The rotation of the nut ring 45 can drive the external threaded tube 41 to move, which facilitates the movement of the external threaded tube 41 and the L-shaped sliding tube 42.
[0053] A baffle 44 is fixedly fitted on the outer wall of the external threaded pipe 41. Two telescopic rods 46 are rotatably provided at the bottom of the baffle 44. The other end of the telescopic rods 46 is rotatably connected to the corresponding second door 3. When the external threaded pipe 41 moves, it can drive the second door 3 to rotate through the telescopic rods 46, thereby driving the second door 3 to open and close automatically.
[0054] Example 2
[0055] refer to Figures 1-10 An improvement based on embodiment 1 is made by providing multiple rectangular openings 38 at the top of the second sliding tube 37. The rectangular openings 38 prevent the foot from blocking the second sliding tube 37 and affecting the cleaning of the foot.
[0056] A pad 4 is provided on one side of the container 1. The pad 4 is located on one side of the second door 3. The pad 4 can be used to easily push the hospital bed into the operating room 15, preventing the hospital bed from needing to be lifted because the bottom of the container 1 is too high.
[0057] A groove corresponding to the gear 43 is provided on one side of the baffle 44. The groove allows the gear 43 to be moved aside, preventing the baffle 44 from hitting and jamming with the gear 43.
[0058] However, as is well known to those skilled in the art, the working principles and wiring methods of the distribution cabinet 6, the first motor 9, and the second motor 11 are commonplace and are all conventional methods or common knowledge. They will not be described in detail here. Those skilled in the art can make any selections according to their needs or convenience.
[0059] Example 3
[0060] refer to Figure 11-13 Improvements based on Example 1:
[0061] A shoe sole disinfection device is installed at pedal 35. The shoe sole disinfection device includes a water collection tank 50 for holding and recovering liquid. Multiple water spray pipes 51 driven by motors are rotatably installed on the upper part of the water collection tank 50 via bearings. The water spray pipes 51 are arranged with a concave arc surface. Spiral reinforcing ribs 52 are evenly distributed on the outer surface of the water spray pipes 51. The spiral reinforcing ribs 52 of adjacent water spray pipes 51 are in opposite directions. The motor and the transmission belt drive pulley drive all the water spray pipes 51 to rotate simultaneously. The spiral reinforcing ribs 52 can clean the shoe sole. At the same time, since the spiral patterns of adjacent spiral reinforcing ribs 52 are opposite and the rotation direction is the same, the two opposite forces cancel each other out, so that the shoe can stand stably during the disinfection process.
[0062] The water spray pipe 51 is provided with a water spray nozzle 56, which is located at the interval of the spiral reinforcing rib 52. As the spiral reinforcing rib 52 rotates, the contact surface between the water spray pipe 51 and the sole of the shoe is constantly changing, so that there are no dead corners when rinsing the shoe surface and it can be completely disinfected.
[0063] A trigger mechanism is inserted into the spray nozzle 56. The trigger mechanism includes a polygonal connecting post 55 in the middle of the bottom buckle 57 and an end 53 at the top. The buckle 57 is an inverted cone shape to facilitate insertion into the spray nozzle 56. When there is water pressure in the spray pipe 51, the buckle 57 is pressed against the inner wall of the spray pipe 51 to seal and fix it. The connecting post 55 is adapted to the spray nozzle 56. A water groove 54 is opened on the connecting post 55. When the end 53 with the arc-shaped outer surface comes into contact with the sole, it will be pressed down. The part of the connecting post 55 with the water groove 54 connects the inside and outside of the spray pipe 51, so that the water inside the spray pipe 51 is sprayed out under pressure, thereby completing the cleaning of the sole.
[0064] The above description is only a preferred embodiment of the present invention, but the scope of protection of the present invention is not limited thereto. Any equivalent substitutions or modifications made by those skilled in the art within the scope of the technology disclosed in the present invention, based on the technical solution and inventive concept of the present invention, should be covered within the scope of protection of the present invention.
Claims
1. A container-integrated operating room, comprising a container (1), characterized in that, One end of the container (1) is closed, and the other end is rotatably provided with two second doors (3). Two partitions (18) are fixedly provided inside the container (1). The two partitions (18) and the second doors (3) divide the container (1) into an operating room (15) for performing surgery, a storage room (17) for holding medical equipment, and a disinfection room (21) for disinfecting medical staff. The container (1) has a first door (2) on one side that is rotatably provided with a corresponding disinfection room (21), and the partition (18) has a fourth door (19) on one side that is rotatably provided with a sealing between the disinfection room (21), the storage room (17) and the operating room (15). The first disinfection unit is set up in the disinfection room (21) to remove dust and disinfect the surface of the medical staff's bodies, and at the same time clean and disinfect the soles of the medical staff's feet; The second disinfection mechanism is set up in the operating room (15) to disinfect the operating room (15) and can automatically open and close the second door (3). The top of the container (1) is provided with a gas box (8) for supplying air to the operating room (15). The top of the container (1) is provided with a power distribution cabinet (6) connected to an external power source for supplying power to the equipment inside the container (1). The first disinfection mechanism includes a disinfection table (20) set in the disinfection chamber (21). The disinfection table (20) is fixedly set on the bottom inner wall of the container (1). A water collection tray (22) is fixedly set on one side of the disinfection table (20). A guide rod (23) is fixedly set between the water collection tray (22) and the container (1). A first screw (24) is rotatably provided through the top of the container (1). A reciprocating screw (34) is fixedly provided at the bottom of the first screw (24). The bottom of the reciprocating screw (34) is rotatably connected to the water collection tray (22). The outer wall of the first screw (24) is threaded with a dust suction ring (27). One side of the dust suction ring (27) is slidably fitted on the guide rod (23). The top of the container (1) is fixedly equipped with a second motor (11). The output end of the second motor (11) is fixedly connected to the first screw (24). The top of the container (1) is fixedly equipped with a vacuum cleaner (12). The air inlet of the vacuum cleaner (12) is connected to the dust suction ring (27) through the first spring tube (25). The outer wall of the reciprocating screw (34) is threaded with a pedal (35). One side of the pedal (35) is slidably fitted on the guide rod (23).
2. The container-integrated operating room according to claim 1, characterized in that, The bottom of the dust suction ring (27) is fixedly provided with a water spray ring (28), and a sliding rod (29) is fixedly provided on one side of the water spray ring (28). The top of the sliding rod (29) is slidably connected to the top of the container (1). The top of the container (1) is fixedly provided with a first water tank (5). The top of the first water tank (5) is slidably provided with a first sliding tube (30). The first sliding tube (30) and the sliding rod (29) are fixedly connected by a connecting plate (31). The top of the first sliding tube (30) is fixedly provided with a connecting tube (32). The other end of the connecting tube (32) extends into the container (1). The water spray ring (28) and the connecting tube (32) are connected by a second spring tube (26). The bottom end of the first sliding tube (30) is fixedly provided with a first rubber cylinder (33).
3. The container-integrated operating room according to claim 2, characterized in that, The water collection tray (22) is provided with a third water tank (36). Multiple second sliding tubes (37) are slidably provided through the top of the third water tank (36). A second rubber cylinder (39) is fixedly provided at the bottom end of the second sliding tube (37). A return spring (40) is sleeved on the outer wall of the second sliding tube (37). The two ends of the return spring (40) are fixedly connected to the third water tank (36) and the second rubber cylinder (39) respectively. The top of the pedal (35) is provided with a through hole corresponding to the second sliding tube (37).
4. The container-type integrated operating room according to claim 1, characterized in that, The second disinfection mechanism includes a connecting frame (14) located in the operating room (15). The connecting frame (14) is fixedly installed on the inner wall of the container (1). A strip nozzle (16) is slidably installed on the inner wall of the connecting frame (14). An external threaded pipe (41) is provided through one side of the connecting frame (14). One end of the external threaded pipe (41) is connected to the strip nozzle (16). An L-shaped sliding pipe (42) is fixedly installed at the other end of the external threaded pipe (41). A second water tank (7) is fixedly installed on the top of the container (1). A connecting cylinder (47) is fixedly installed on the inner wall of the second water tank (7). The L-shaped sliding pipe (42) is slidably installed through one side of the second water tank (7) and located inside the connecting cylinder (47). A piston ring (49) is slidably installed on the inner wall of the connecting cylinder (47). The piston ring (49) is fixedly sleeved on the L-shaped sliding pipe (42). Two water holes (48) are opened on the outer wall of the connecting cylinder (47).
5. The container-type integrated operating room according to claim 4, characterized in that, A nut ring (45) is rotatably provided on one side of the connecting frame (14). A first motor (9) is fixedly provided on the top of the container (1). The output end of the first motor (9) and the outer wall of the nut ring (45) are both fixedly fitted with meshing gears (43). The nut ring (45) is threaded onto the external threaded pipe (41).
6. The container-integrated operating room according to claim 5, characterized in that, The outer wall of the external threaded tube (41) is fixedly fitted with a baffle (44), and two telescopic rods (46) are rotatably provided at the bottom of the baffle (44). The other end of the telescopic rods (46) is rotatably connected to the corresponding second door body (3). A groove corresponding to the gear (43) is opened on one side of the baffle (44).
7. A container-type integrated operating room according to claim 3, characterized in that, The top of the second sliding tube (37) has multiple rectangular openings (38).
8. A container-type integrated operating room according to any one of claims 1-6, characterized in that, A pad (4) is provided on one side of the container (1), and the pad (4) is located on one side of the second door (3).
9. A container-type integrated operating room according to claim 1, characterized in that, A shoe sole disinfection device is installed at the pedal (35). The shoe sole disinfection device includes a water pool (50). Multiple water spray pipes (51) driven by motors are rotatably installed on the upper part of the water pool (50) through bearings. The water spray pipes (51) are arranged in a concave arc shape. Spiral reinforcing ribs (52) are evenly distributed on the outer surface of the water spray pipes (51). A water spray nozzle (56) is opened on the water spray pipes (51). The water spray nozzle (56) is located at the interval of the spiral reinforcing ribs (52). A trigger mechanism is inserted in the water spray nozzle (56). The trigger mechanism includes a polygonal connecting post (55) in the middle of the bottom buckle (57) and an end (53) at the top. The connecting post (55) is adapted to the water spray nozzle (56). A water groove (54) is opened on the connecting post (55).