CN219175986U - Combined type composite operation platform capable of being rapidly deployed - Google Patents

Abstract

The utility model provides a combined type composite operation platform capable of being rapidly deployed, which comprises an operation room shelter, a DSA shelter, a CT shelter and a nuclear magnetic shelter, wherein the CT shelter is arranged on one side of the DSA shelter in the horizontal direction, the nuclear magnetic shelter is arranged on the other side of the DSA shelter in the horizontal direction, the operation room shelter is arranged on one side of the DSA shelter in the vertical direction, and the DSA shelter is fixedly connected with the operation room shelter, the CT shelter and the nuclear magnetic shelter through connecting devices; the operation room shelter and the DSA shelter adopt single expansion shelter bodies, the CT shelter and the nuclear magnetic shelter adopt double expansion shelter bodies, wherein DSA equipment is arranged in the DSA shelter, CT equipment is arranged in the CT shelter, and nuclear magnetic equipment is arranged in the nuclear magnetic shelter. The single module in the utility model can be independently transported, independently used, and used for respectively unfolding the examination of CT, nuclear magnetism, DSA and the like, and can be rapidly combined into an integral composite operating room, thereby remarkably improving the maneuverability, flexibility and utilization rate.

Description

Combined type composite operation platform capable of being rapidly deployed

Technical Field

The utility model belongs to the technical field of operating rooms, and particularly relates to a combined type composite operating platform capable of being rapidly deployed.

Background

The compound operating room is formed by comprehensively integrating 3D imaging technologies of DSA (digital subtraction angiography), CT (computed tomography), MRI (Magnetic ResonanceImaging), and other devices with surgery in a clean operating room, so that minimally invasive interventional surgery is combined with traditional open surgery, various complex surgeries are solved, surgery risks are reduced, and surgery time is saved. The appearance of the compound operating room enables the operating room to be more specialized, digitized, integrated and modularized, and systematic promotion of the development of the operating room is achieved. The clinical significance of the method is that major operations which can be completed in different operating rooms and stages are combined in one operating room at a time. Breaks through the subject barriers, and organically combines the advantages of surgical treatment by taking patients as the center and combining multiple subjects by means of a brand new compound surgical facility. The compound operating room has the great advantage of improving the operating efficiency, further improving the hospital treatment capacity and reducing the patient stay time, so that the sickbed utilization rate is improved.

The existing mainstream composite operating room has large occupied area, long construction period, poor transportation convenience of the used equipment and insufficient environmental adaptability, so that the equipment is limited to a few large hospitals and is difficult to be applied to occasions such as primary hospitals, disaster site rescue and the like.

Disclosure of Invention

Aiming at the problems, the utility model provides a combined type composite operation platform capable of being rapidly deployed.

The combined type composite operation platform capable of being rapidly deployed comprises an operation room shelter, a DSA shelter, a CT shelter and a nuclear magnetic shelter, wherein the CT shelter is arranged on one side of the horizontal direction of the DSA shelter, the nuclear magnetic shelter is arranged on the other side of the horizontal direction of the DSA shelter, the operation room shelter is arranged on one side of the vertical direction of the DSA shelter, and the DSA shelter is fixedly connected with the operation room shelter, the CT shelter and the nuclear magnetic shelter through connecting devices; the operation room shelter and the DSA shelter adopt single expansion cabins, the CT shelter and the nuclear magnetic shelter adopt double expansion cabins, wherein DSA equipment is arranged in the DSA shelter, CT equipment is arranged in the CT shelter, and nuclear magnetic equipment is arranged in the nuclear magnetic shelter; the DSA shelter comprises a second shelter body, the first shelter body is far away from the second shelter body, one side of the first shelter body is provided with the first expansion shelter body which can be movably connected, a first shelter body bottom plate is close to one side of the second shelter body and is provided with a second connecting plate, bolt holes are uniformly formed in the surface of the second connecting plate, and one side of the first shelter body bulkhead close to the second shelter body is provided with a second sliding door.

Further, the DSA shelter includes the second expansion cabin body, the CT shelter includes the third cabin body, the nuclear magnetism shelter includes the fourth cabin body, the second cabin body is kept away from first cabin body one side is equipped with swing joint the second expansion cabin body, the second cabin body bottom plate is close to first cabin body the third cabin body with one side of the fourth cabin body all is equipped with first connecting plate be used for with the second connecting plate of first cabin body one side the third connecting plate of third cabin body one side with the fourth connecting plate of fourth cabin body one side is connected, the bolt hole has evenly been seted up on first connecting plate surface, install first slide rail in the second cabin body bottom plate middle part horizontal direction, the second slide rail is installed in the second cabin body bottom plate middle part vertical direction, first slide rail with first slide rail has all been seted up at second slide rail top middle part, swing joint has first removal base on the first slide rail, first removal base is used for installing DSA device the second cabin body is close to first cabin body and the fourth cabin body one side.

Further, the CT square cabin comprises a third expansion cabin body and a fourth expansion cabin body, one side of the vertical direction of the third cabin body is provided with the third expansion cabin body, the other side of the vertical direction of the third cabin body is provided with the fourth expansion cabin body, a third connecting plate is arranged on one side, close to the second cabin body, of a bottom plate of the third cabin body, bolt holes are uniformly formed in the surface of the third connecting plate, a third sliding door is arranged on one side, close to the second cabin body, of a bulkhead of the third cabin body, a third sliding rail is arranged in the horizontal direction of the middle of a bottom plate in the third cabin body, a fourth sliding rail is arranged in the vertical direction of the middle of the bottom plate in the third cabin body, second sliding grooves are formed in the middle of the top ends of the third sliding rail and the fourth sliding rail, a second moving base is slidably connected with the second sliding groove, and the second moving base is used for mounting CT equipment, and a seventh sliding rail is arranged in the vertical direction of the middle of the bottom plate in the fourth expansion cabin body; when the fourth expansion cabin body is expanded, one end of the seventh sliding rail is connected with one end of the fourth sliding rail.

Further, the nuclear magnetic square cabin comprises a fifth expansion cabin body and a sixth expansion cabin body, one side of the vertical direction of the fourth cabin body is provided with the fifth expansion cabin body, the other side of the vertical direction of the fourth cabin body is provided with the sixth expansion cabin body, a fourth connecting plate is arranged on one side, close to the second cabin body, of a bottom plate of the fourth cabin body, bolt holes are uniformly formed in the surface of the fourth connecting plate, a fourth sliding door is arranged on one side, close to the second cabin body, of a bulkhead of the fourth cabin body, a fifth sliding rail is arranged in the horizontal direction of the middle of a bottom plate in the fourth cabin body, a sixth sliding rail is arranged in the vertical direction of the middle of the bottom plate in the fourth cabin body, third sliding grooves are formed in the middle of the top ends of the fifth sliding rail and are slidably connected with a third moving base, and the third moving base is used for mounting nuclear magnetic equipment; an eighth sliding rail is arranged in the middle of the bottom plate in the sixth expansion cabin in the vertical direction; when the sixth expansion cabin body is expanded, one end of the eighth sliding rail is connected with one end of the sixth sliding rail.

Further, the connecting device comprises a connecting frame, a connecting plate and a fourth sliding groove, bolt holes are symmetrically formed in two sides of the connecting frame, the connecting plate is mounted at the top end of the connecting frame, and the fourth sliding groove is formed in the top end of the connecting plate.

Further, the first movable base, the second movable base and the third movable base comprise a bottom fixing seat, a sliding block, pulleys and foot brakes, the sliding block is installed in the middle of the bottom end of the bottom fixing seat, the pulleys are symmetrically installed on two sides of the bottom end of the bottom fixing seat, and the foot brakes are arranged in the middle of the pulleys.

Further, the pulley is a universal wheel.

Further, anti-skid patterns are arranged on the surfaces of the first sliding rail, the second sliding rail, the third sliding rail, the fourth sliding rail, the fifth sliding rail and the sixth sliding rail.

Further, the operating room shelter comprises an operating bed, a medical crane, a breathing machine, a monitor, an injection pump, a display screen and an operating lamp.

Further, the first expansion cabin body, the second expansion cabin body, the third expansion cabin body, the fourth expansion cabin body, the fifth expansion cabin body and the sixth expansion cabin body are all provided with door frames, and one side of each door frame is connected with a cabin door through a hinge.

The combined type composite operation platform capable of being rapidly deployed can be used by a single module in an independent transportation mode, can be used independently, can be used for respectively unfolding the CT, nuclear magnetism, DSA and other aspects of inspection, can be rapidly combined into an integral composite operation room, can be used as an operation room alone, can be used as a preoperative preparation room and a postoperative observation room in a combined deployment state, and has remarkable improvement in maneuverability, flexibility and use ratio; the composite operation maneuvering platform takes the CAF40 shelter as a carrier, can meet most transportation requirements, and has obvious improvement on adaptability.

Additional features and advantages of the utility model will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the utility model. The objectives and other advantages of the utility model may be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions of the prior art, the following description will briefly explain the drawings used in the embodiments or the description of the prior art, and it is obvious that the drawings in the following description are some embodiments of the present utility model, and other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic three-dimensional view of a rapidly deployable composite surgical platform in accordance with an embodiment of the utility model;

FIG. 2 shows a schematic plan view of a rapidly deployable composite surgical platform in accordance with an embodiment of the present utility model;

FIG. 3 shows a schematic view of the structure of an operating room shelter in an embodiment of the utility model;

FIG. 4 shows a schematic structural view of a DSA shelter in an embodiment of the present utility model;

FIG. 5 shows a schematic structural view of a CT square cabin in an embodiment of the utility model;

FIG. 6 shows a schematic diagram of the structure of a nuclear magnetic shelter in an embodiment of the utility model;

FIG. 7 is a schematic view showing a mounting structure of a slider in an embodiment of the present utility model;

FIG. 8 is a schematic view showing the structure of a connecting device in an embodiment of the present utility model;

FIG. 9 shows a schematic view of an operating room shelter in an embodiment of the utility model after expansion;

FIG. 10 is a schematic view of an operating room shelter in an embodiment of the utility model;

FIG. 11 shows a schematic diagram of an expanded DSA shelter in an embodiment of the present utility model;

FIG. 12 shows a schematic view of a DSA shelter in an embodiment of the present utility model after being collapsed;

FIG. 13 shows a schematic view of an expanded CT shelter in an embodiment of the present utility model;

FIG. 14 is a schematic view of a CT shelter according to an embodiment of the present utility model after being collapsed;

FIG. 15 shows a schematic view of an expanded nuclear magnetic shelter in an embodiment of the utility model;

fig. 16 shows a schematic diagram of a collapsed nuclear magnetic shelter according to an embodiment of the present utility model.

Reference numerals:

1. an operating room shelter; 11. a first compartment; 12. a first expansion tank; 13. a second connecting plate; 14. a second sliding door; 15. an operating bed; 2. a DSA shelter; 21. a second compartment; 22. the second expansion cabin body; 23. a first connection plate; 24. a first slide rail; 25. a second slide rail; 26. a first chute; 27. a first mobile base; 28. a first sliding door; 3. CT square cabin; 31. a third compartment; 32. a third expansion tank; 33. a fourth expansion tank; 34. a third connecting plate; 35. a third sliding door; 36. a third slide rail; 37. a fourth slide rail; 38. a second chute; 39. a second movable base; 310. a seventh slide rail; 4. nuclear magnetic shelter; 41. a fourth compartment; 42. a fifth expansion tank; 43. a sixth expansion tank; 44. a fourth connecting plate; 45. a fourth sliding door; 46. a fifth slide rail; 47. a sixth slide rail; 48. a third chute; 49. a third movable base; 410. an eighth slide rail; 5. a connecting device; 51. a connecting frame; 52. a splice plate; 53. a fourth chute; 61. a bottom fixing seat; 62. a slide block; 63. a pulley; 64. a foot brake; 6. a DSA device; 7. a CT apparatus; 8. nuclear magnetic equipment.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments of the present utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The utility model provides a combined type composite operation platform capable of being rapidly deployed. FIG. 1 is a schematic three-dimensional view of a rapidly deployable modular composite surgical platform in accordance with an embodiment of the utility model. As shown in fig. 1 and 2, the quickly-deployed combined type composite operation platform comprises an operation room shelter 1, a DSA shelter 2, a CT shelter 3 and a nuclear magnetic shelter 4, wherein the CT shelter 3 is arranged on one side of the DSA shelter 2 in the horizontal direction, the nuclear magnetic shelter 4 is arranged on the other side of the DSA shelter 2 in the horizontal direction, the operation room shelter 1 is arranged on one side of the DSA shelter 2 in the vertical direction, and the DSA shelter 2, the operation room shelter 1, the CT shelter 3 and the nuclear magnetic shelter 4 are fixedly connected through a connecting device 5; the operation room shelter 1 and the DSA shelter 2 adopt single expansion cabins, the CT shelter 3 and the nuclear magnetic shelter 4 adopt double expansion cabins, wherein DSA equipment 6 is arranged in the DSA shelter 2, CT equipment 7 is arranged in the CT shelter 3, and nuclear magnetic equipment 8 is arranged in the nuclear magnetic shelter 4.

The operating room shelter 1, the DSA shelter 2, the CT shelter 3 and the nuclear magnetic shelter 4 in the embodiment of the utility model are cabins based on CAF 40. The deployment mode of the combined type composite operation platform capable of being rapidly deployed is that the DSA square cabin 2 is taken as the center, the CT square cabin 3 and the nuclear magnetic square cabin 4 are distributed at two ends of the DSA square cabin in a straight line, and the operation room square cabin 1 is arranged at one side of the square cabin of the DSA equipment 6. The DSA capsule 2, CT capsule 3, nuclear magnetic capsule 4 and operating room capsule 1 are arranged so that the patient performs the corresponding examination and surgery. In order to keep the stability among the DSA shelter 2, the CT shelter 3, the nuclear magnetic shelter 4 and the operating room shelter 1, the cabins are connected through a connecting device 5 and are fixed by bolts.

The DSA device 6 is provided in the DSA shelter 2, the CT device 7 is provided in the CT shelter 3, and the nuclear magnetic device 8 is provided in the nuclear magnetic shelter 4. The equipment in each shelter is used for carrying out corresponding treatment on patients.

In some embodiments, as shown in fig. 3, the operating room shelter 1 includes a first cabin 11 and a first expansion cabin 12, the dsa shelter 2 includes a second cabin 21, a side, away from the second cabin 21, of the first cabin 11 is provided with a first expansion cabin 12 capable of being movably connected, a side, close to the second cabin 21, of a bottom plate of the first cabin 11 is provided with a second connecting plate 13, the surface of the second connecting plate 13 is uniformly provided with bolt holes, and a side, close to the second cabin 21, of the bulkhead of the first cabin 11 is provided with a second sliding door 14.

Fig. 9 is a schematic diagram of an expanded operating room shelter according to an embodiment of the present utility model, and fig. 10 is a schematic diagram of a collapsed operating room shelter according to an embodiment of the present utility model.

In some embodiments, as shown in fig. 4, the DSA square cabin 2 includes a second expansion cabin 22, the ct square cabin 3 includes a third cabin 31, the nuclear magnetic square cabin 4 includes a fourth cabin 41, a second expansion cabin 22 movably connected is disposed on a side of the second cabin 21 far away from the first cabin 11, a first connecting plate 23 is disposed on a side of a bottom plate of the second cabin 21 close to the first cabin 11, the third cabin 31 and the fourth cabin 41, the first connecting plate 23 is used for connecting with a second connecting plate 13 on a side of the first cabin 11, a third connecting plate 34 on a side of the third cabin 31 and a fourth connecting plate 44 on a side of the fourth cabin 41, bolt holes are uniformly formed on a surface of the first connecting plate 23, a first slide rail 24 is mounted on a horizontal direction in a middle part of a bottom plate in the second cabin 21, a first slide rail 25 is mounted on a vertical direction in a middle part of a bottom plate of the second cabin 21, a first slide rail 26 is disposed on a middle part of a top end of the first slide rail 24, a first moving base 27 is movably connected to the first slide rail 24, and the first moving base 27 is used for mounting the DSA device 21 and the first cabin 11 and the fourth cabin 41 is disposed on a side of the first cabin 31.

Specifically, in connecting the operating room shelter 1 and the DSA shelter 2, the connection frame 51 is placed on the second connection plate 13 of the first shelter 11 and the first connection plate 23 of the second expansion shelter 22 close to the first shelter 11, wherein bolt holes on both sides of the connection frame 51 are aligned with the bolt holes on the second connection plate 13 and the first connection plate 23, respectively, so that the connection frame 51 is fixed with the second connection plate 13 and the first connection plate 23 by bolts.

Further specifically, as shown in fig. 7, a first sliding rail 24 and a second sliding rail 25 which are perpendicular to each other are arranged on the ground of the second cabin body 21 of the DSA square cabin 2, the first sliding rail 24 and the second sliding rail 25 which are perpendicular to each other are provided with a first sliding groove 26 which penetrates through, a sliding block 62 is arranged at the bottom of the first moving base 27, and the sliding block 62 can be clamped in the first sliding groove 26, so that a pulley 63 at the bottom of the first moving base 27 can move along the first sliding rail 24 and the second sliding rail 25. Fig. 11 shows a schematic diagram of an expanded DSA shelter according to an embodiment of the present utility model, and fig. 12 shows a schematic diagram of a collapsed DSA shelter according to an embodiment of the present utility model.

It should be noted that the DSA apparatus 6 is fixed on the first moving base 27, so that the DSA apparatus 6 can be pushed to move along the first slide rail 24 and the second slide rail 25.

In some embodiments, as shown in fig. 5, the CT shelter 3 includes a third expansion shelter 32 and a fourth expansion shelter 33, one side of the vertical direction of the third shelter 31 is provided with the third expansion shelter 32, the other side of the vertical direction of the third shelter 31 is provided with the fourth expansion shelter 33, the bottom plate of the third shelter 31 is provided with a third connecting plate 34 near the side of the second shelter 21, the surface of the third connecting plate 34 is uniformly provided with bolt holes, the side of the bulkhead of the third shelter 31 near the second shelter 21 is provided with a third sliding door 35, a third sliding rail 36 is installed in the horizontal direction of the middle part of the bottom plate in the third shelter 31, a fourth sliding rail 37 is installed in the vertical direction of the middle part of the bottom plate in the third shelter 31, the top ends of the third sliding rail 36 and the fourth sliding rail 37 are provided with second sliding grooves 38, the second sliding grooves 38 are slidably connected with a second movable base 39, the second movable base 39 is used for installing the CT apparatus 7, and a seventh sliding rail 310 is installed in the vertical direction of the middle part of the bottom plate in the fourth expansion shelter 33; when the fourth expansion tank 33 is expanded, one end of the seventh slide rail 310 is engaged with one end of the fourth slide rail 37.

Specifically, in connecting the CT shelter 3 and the DSA shelter 2, the connection frame 51 is placed on the third connection plate 34 of the third shelter 31 and the first connection plate 23 of the second expansion shelter 22 close to the third shelter 31, wherein bolt holes on both sides of the connection frame 51 are aligned with the bolt holes on the third connection plate 34 and the first connection plate 23, respectively, so that the connection frame 51 is fixed together with the third connection plate 34 and the first connection plate 23 by bolts.

More specifically, a third sliding rail 36 and a fourth sliding rail 37 which are perpendicular to each other are arranged on the ground of the third cabin body 31 of the CT square cabin 3, wherein a seventh sliding rail 310 is further arranged on the fourth expansion cabin body 33 on one side of the third cabin body 31, and one end of the seventh sliding rail 310 is connected with one end of the fourth sliding rail 37 when the fourth expansion cabin body 33 is expanded. The bottom of the second moving base 39 is provided with a sliding block 62, and the sliding block 62 can be clamped in the second sliding groove 38 which is mutually communicated with the third sliding rail 36, the fourth sliding rail 37 and the seventh sliding rail 310, so that the pulley 63 at the bottom of the second moving base 39 can move along the third sliding rail 36, the fourth sliding rail 37 and the seventh sliding rail 310. Fig. 13 is a schematic diagram of an expanded CT shelter according to an embodiment of the present utility model, and fig. 14 is a schematic diagram of a collapsed CT shelter according to an embodiment of the present utility model.

It should be noted that the CT apparatus 7 is fixed on the second moving base 39, so that the CT apparatus 7 can be pushed to move along the third slide rail 36, the fourth slide rail 37, and the seventh slide rail 310.

In some embodiments, as shown in fig. 6, the nuclear magnetic square cabin 4 includes a fifth expansion cabin 42 and a sixth expansion cabin 43, one side of the vertical direction of the fourth cabin 41 is provided with the fifth expansion cabin 42, the other side of the vertical direction of the fourth cabin 41 is provided with the sixth expansion cabin 43, the bottom plate of the fourth cabin 41 is provided with a fourth connecting plate 44 near the second cabin 21, the surface of the fourth connecting plate 44 is uniformly provided with bolt holes, the side of the bulkhead of the fourth cabin 41 near the second cabin 21 is provided with a fourth sliding door 45, a fifth sliding rail 46 is installed in the horizontal direction of the middle part of the bottom plate in the fourth cabin 41, a sixth sliding rail 47 is installed in the vertical direction of the middle part of the bottom plate in the fourth cabin 41, third sliding grooves 48 are respectively provided at the top ends of the fifth sliding rail 46 and the sixth sliding rail 47, the third sliding grooves 48 are slidably connected with a third moving base 49, and the third moving base 49 is used for installing the nuclear magnetic equipment 8; an eighth slide rail 410 is arranged in the vertical direction of the middle part of the bottom plate in the sixth expansion cabin 43; when the sixth expansion tank 43 is expanded, one end of the eighth slide rail 410 engages one end of the sixth slide rail 47. Fig. 15 shows a schematic diagram of an expanded nuclear magnetic shelter according to an embodiment of the present utility model, and fig. 16 shows a schematic diagram of a collapsed nuclear magnetic shelter according to an embodiment of the present utility model.

Specifically, in connecting the nuclear magnetic square cabin 4 and the DSA square cabin 2, the connection frame 51 is placed on the fourth connection plate 44 of the fourth cabin 41 and the first connection plate 23 of the second expansion cabin 22 close to the third cabin 31, wherein bolt holes on both sides of the connection frame 51 are aligned with the bolt holes on the fourth connection plate 44 and the first connection plate 23, respectively, so that the connection frame 51 is fixed with the fourth connection plate 44 and the first connection plate 23 by bolts.

More specifically, a fifth sliding rail 46 and a sixth sliding rail 47 which are perpendicular to each other are arranged on the ground of the fourth cabin 41 of the nuclear magnetic square cabin 4, wherein the sixth expansion cabin 43 on one side of the fourth cabin 41 is further provided with an eighth sliding rail 410, and one end of the eighth sliding rail 410 is connected with one end of the sixth sliding rail 47 when the sixth expansion cabin 43 is expanded. The bottom of the third moving base 49 is provided with a sliding block 62, and the sliding block 62 can be clamped in the third sliding groove 48 of the interconnected house of the fifth sliding rail 46, the sixth sliding rail 47 and the eighth sliding rail 410, so that the pulley 63 at the bottom of the third moving base 49 can be along the fifth sliding rail 46, the sixth sliding rail 47 and the eighth sliding rail 410.

It should be noted that the nuclear magnetic device 8 is fixed on the third moving base 49, so that the nuclear magnetic device 8 can be pushed to move along the fifth sliding rail 46, the sixth sliding rail 47, and the eighth sliding rail 410.

In the case of a combined operation, the CT table of the CT apparatus 7 can be moved to the fourth expansion chamber 33 side via the fourth slide rail 37, and the DSA apparatus 3 can be moved to the expansion chamber side via the shelter top slide rail, and the third sliding door 35 of the CT shelter 3 and the first sliding door 28 of the DSA shelter 2 are opened. The CT apparatus 7 may enter the DSA shelter 6 through the third slide rail 36 and the fourth slide groove 53 of the connector plate 52. After entry, the third sliding door 35 and the first sliding door 28 are closed for use. The nuclear magnetic device 8 is used in principle as the CT device 7. And will not be described in detail herein.

For better effect, silica gel cushions are symmetrically arranged on the two sides of the top ends of the first chute 26, the second chute 38 and the third chute 48. When the DSA device 6, the CT device 7 or the nuclear magnetic device 8 is pushed, the first moving base 27, the second moving base 39 or the sliding block 62 at the bottom of the nuclear magnetic device 8, or the bottom of the DSA device 6, the CT device 7 or the nuclear magnetic device 8 can prop open the silica gel cushion, and the silica gel cushion can be closed after the sliding block 62 slides, so that foreign matters can be prevented from entering the first sliding groove 26, the second sliding groove 38 and the third sliding groove 48 to block the movement of the DSA device 6, the CT device 7 or the nuclear magnetic device 8.

In some embodiments, as shown in fig. 8, the connection device 5 includes a connection frame 51, a connection plate 52 and a fourth sliding groove 53, bolt holes are symmetrically formed on two sides of the connection frame 51, the connection plate 52 is mounted on the top end of the connection frame 51, and the fourth sliding groove 53 is formed on the top end of the connection plate 52.

Specifically, in the case of a complex operation, the CT apparatus 7 or the nuclear magnetic apparatus 8 may be moved into the DSA shelter 2 in order to facilitate the detection of the patient. The adapter plate 52 is placed on the connection frame 51 while the operating room capsule 1, the DSA capsule 2, the CT capsule 3, and the nuclear magnetic capsule 4 are fixed together by the connection frame 51. It should be noted that, the fourth chute 53 formed on the connection plate 52 may facilitate the sliding block 62 of the first moving base 27, the second moving base 39 or the third moving base 49 to move the CT apparatus 7 or the nuclear magnetic apparatus 8 into the DSA shelter 2 through the fourth chute 53 on the connection plate 52.

Wherein, when the CT apparatus 7 is moved to the DSA square cabin 2, the first moving door 28 of the second cabin 21, which is close to the third cabin 31, and the third moving door 35 of the third cabin 31, which is close to the second cabin 21, are opened to move the CT apparatus 7 to the DSA square cabin 2. When the nuclear magnetic device 8 is moved into the DSA shelter 2, the first sliding door 28 of the second compartment 21, which is adjacent to the fourth compartment 41, and the fourth sliding door 45 of the fourth compartment 41, which is adjacent to the second compartment 21, are opened to move the nuclear magnetic device 8 into the DSA shelter 2.

When the CT apparatus 7 or the nuclear magnetic apparatus 8 is moved into the DSA square cabin 2, the DSA apparatus 6 is moved onto the second rail 25 of the second cabin 21, and the CT apparatus 7 or the nuclear magnetic apparatus 8 is moved onto the first rail 24 of the second cabin 21.

In some embodiments, the first moving base 27, the second moving base 39 and the third moving base 49 all comprise a bottom fixing base 61, a sliding block 62, a pulley 63 and a foot brake 64, the sliding block 62 is installed in the middle of the bottom end of the bottom fixing base 61, the pulley 63 is symmetrically installed on two sides of the bottom end of the bottom fixing base 61, and the foot brake 64 is arranged in the middle of the pulley 63.

Specifically, slide rail devices are installed on the bottom plates of the operating room shelter 1, the DSA shelter 2, the CT shelter 3 and the nuclear magnetic shelter 4, movable bases are installed at the bottoms of the DSA equipment 6, the CT equipment 7 and the nuclear magnetic equipment 8, and the movable bases at the bottoms of the DSA equipment 6, the CT equipment 7 and the nuclear magnetic equipment 8 can move among the cabins and meet the fixed requirements during transportation.

The pulley 63 may be turned, i.e., may move along a horizontal rail or a vertical rail. The pulley 63 may be a universal wheel.

More specifically, the sliding block 62 is clamped in the sliding grooves 48 formed on the first sliding rail 24, the second sliding rail 25, the third sliding rail 36, the fourth sliding rail 37, the fifth sliding rail 46 and the sixth sliding rail 47, so that the moving base cannot deviate from the sliding rails when pushing the DSA device 6, the CT device 7 or the nuclear magnetic device 8. When the DSA device 6, the CT device 7 or the nuclear magnetic device 8 is fixed, the pulley 63 at the bottom of the first moving base 27, the second moving base 39 or the third moving base 49 moves on the slide rail by pushing the DSA device 6, the CT device 7 or the nuclear magnetic device 8, and after moving to a proper position, the foot brake 64 is pressed down to fix.

In some embodiments, the surfaces of the first rail 24, the second rail 25, the third rail 36, the fourth rail 37, the fifth rail 46, and the sixth rail 47 are provided with anti-skid patterns.

Specifically, the anti-skid patterns on the surfaces of the first slide rail 24, the second slide rail 25, the third slide rail 36, the fourth slide rail 37, the fifth slide rail 46 and the sixth slide rail 47 are used for increasing the friction force on the surfaces of the first slide rail 24, the second slide rail 25, the third slide rail 36, the fourth slide rail 37, the fifth slide rail 46 and the sixth slide rail 47. The DSA device 6, the CT device 7, and the nuclear magnetic device 8 are controlled to be fixed by stepping on a foot brake 64 provided on the pulley 63. The anti-skid patterns can increase friction force between the pulley 63 and the first slide rail 24, the second slide rail 25, the third slide rail 36, the fourth slide rail 37, the fifth slide rail 46 and the sixth slide rail 47, and prevent the DSA device 6, the CT device 7 and the nuclear magnetic device 8 from moving in a fixed manner. Meanwhile, the anti-skid patterns on the surfaces of the first slide rail 24, the second slide rail 25, the third slide rail 36, the fourth slide rail 37, the fifth slide rail 46 and the sixth slide rail 47 can also prevent a doctor or a patient from falling down when stepping on the slide rails.

In some embodiments, the operating room shelter 1 includes an operating table 15, a medical pylon, a ventilator, a monitor, a syringe pump, a display screen, and an operating light.

The operation room shelter 1 is a unilateral expansion cabin which is arranged in a furled state as shown in fig. 10, and is arranged in an unfolded state as shown in fig. 9, and is provided with an operation bed 15, an operation lamp, a medical crane, a monitor, a breathing machine, a four-way injection pump and other devices, wherein a display screen is arranged inside the operation room shelter 1, and the operation lamp is fixed on the top of the operation room shelter 1 so as to facilitate the operation on a patient. The operating room wounded can enter the DSA shelter 2 through the second sliding door 14 of the first shelter 11 and the first sliding door 28 of the second shelter 21 for corresponding image-wise examination.

In some embodiments, the bulkheads of the first expansion tank 12, the second expansion tank 22, the third expansion tank 32, the fourth expansion tank 33, the fifth expansion tank 42, and the sixth expansion tank 43 are all provided with door frames, and one side of each door frame is connected with a cabin door through a hinge.

Specifically, the CT shelter 3 and the nuclear magnetic shelter 4 may be used separately, and when the CT shelter 3 is used separately, a doctor may enter the operation room of the CT shelter 3 through the door of the third expansion cabin 32, and an operation console of the CT apparatus is disposed in the third expansion cabin 32. The wounded person can enter the CT shelter 3 through the fourth expansion shelter 33. When the nuclear magnetic square cabin 4 is used alone, doctors can enter the operation room of the nuclear magnetic square cabin 4 through the cabin door of the fifth expansion cabin body 42, an operation table of the nuclear magnetic equipment 8 is arranged in the fifth expansion cabin body 42, and wounded persons can enter the nuclear magnetic square cabin 4 through the cabin door of the sixth expansion cabin body 43 for examination.

The combined type composite operation platform capable of being rapidly deployed can be used by a single module in an independent transportation mode, can be used independently, can be used for respectively unfolding the CT, nuclear magnetism, DSA and other aspects of inspection, can be rapidly combined into an integral composite operation room, can be used as an operation room alone, can be used as a preoperative preparation room and a postoperative observation room in a combined deployment state, and has remarkable improvement in maneuverability, flexibility and use ratio; the composite operation maneuvering platform takes the CAF40 shelter as a carrier, can meet most transportation requirements, and has obvious improvement on adaptability.

Although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present utility model.

Claims (10)

1. A combined type composite operation platform capable of being rapidly deployed is characterized by comprising an operation room shelter (1), a DSA shelter (2), a CT shelter (3) and a nuclear magnetic shelter (4),

the CT square cabin (3) is arranged on one side of the DSA square cabin (2) in the horizontal direction, the nuclear magnetic square cabin (4) is arranged on the other side of the DSA square cabin (2) in the horizontal direction, the operating room square cabin (1) is arranged on one side of the DSA square cabin (2) in the vertical direction, and the DSA square cabin (2) is fixedly connected with the operating room square cabin (1), the CT square cabin (3) and the nuclear magnetic square cabin (4) through a connecting device (5);

the operation room shelter (1) and the DSA shelter (2) adopt single expansion cabins, the CT shelter (3) and the nuclear magnetic shelter (4) adopt double expansion cabins, wherein DSA equipment (6) is arranged in the DSA shelter (2), CT equipment (7) is arranged in the CT shelter (3), and nuclear magnetic equipment (8) is arranged in the nuclear magnetic shelter (4);

the operating room shelter (1) comprises a first shelter body (11) and a first expansion shelter body (12), the DSA shelter (2) comprises a second shelter body (21), the first shelter body (11) is far away from one side of the second shelter body (21) and is provided with the first expansion shelter body (12) capable of being movably connected, a bottom plate of the first shelter body (11) is close to one side of the second shelter body (21) and is provided with a second connecting plate (13), bolt holes are evenly formed in the surface of the second connecting plate (13), and a wall of the first shelter body (11) is close to one side of the second shelter body (21) and is provided with a second sliding door (14).

2. The rapid deployment combined type composite operation platform according to claim 1, wherein the DSA square cabin (2) comprises a second expansion cabin body (22), the CT square cabin (3) comprises a third cabin body (31), the nuclear magnetic square cabin (4) comprises a fourth cabin body (41), the second cabin body (21) is far away from one side of the first cabin body (11) and is provided with the second expansion cabin body (22) which can be movably connected, the bottom plate of the second cabin body (21) is close to one side of the first cabin body (11), one side of the third cabin body (31) and one side of the fourth cabin body (41) are respectively provided with a first connecting plate (23), the first connecting plate (23) is used for being connected with a second connecting plate (13) on one side of the first cabin body (11), a third connecting plate (34) on one side of the third cabin body (31) and a fourth connecting plate (44) on one side of the fourth cabin body (41), the surface of the first connecting plate (23) is uniformly provided with a second cabin body (21), one side of the second cabin body (21) is provided with a second connecting plate (24), one side of the second cabin body (25) is provided with a second connecting plate (25), one side of the second cabin body (25) is provided with a second sliding rail (25), the novel DSA is characterized in that a first movable base (27) is movably connected to the first sliding rail (24), the first movable base (27) is used for installing the DSA equipment (6), and a first movable door (28) is arranged on one side, close to the first cabin (11), of the bulkhead of the second cabin (21), of the third cabin (31) and of the fourth cabin (41).

3. The rapid deployment combined type composite operation platform according to claim 2, wherein the CT shelter (3) comprises a third expansion shelter body (32) and a fourth expansion shelter body (33), one side of the third shelter body (31) in the vertical direction is provided with the third expansion shelter body (32), the other side of the third shelter body (31) in the vertical direction is provided with the fourth expansion shelter body (33), one side of a bottom plate of the third shelter body (31) close to the second shelter body (21) is provided with a third connecting plate (34), the surface of the third connecting plate (34) is uniformly provided with a bolt hole, one side of a bulkhead of the third shelter body (31) close to the second shelter body (21) is provided with a third sliding door (35), the middle part of the bottom plate in the third shelter body (31) is horizontally provided with a third sliding rail (36), the middle part of the bottom plate in the third shelter body (31) is vertically provided with a fourth sliding rail (37), the third sliding rail (36) and the top end of the fourth sliding rail (37) are provided with a second sliding groove (38), the bottom plate (39) is vertically provided with a second sliding groove (39), and the bottom plate (39) is vertically provided with a second sliding groove (39);

when the fourth expansion cabin (33) is expanded, one end of the seventh sliding rail (310) is connected with one end of the fourth sliding rail (37).

4. The rapid deployment combined type composite operation platform according to claim 3, wherein the nuclear magnetic square cabin (4) comprises a fifth expansion cabin body (42) and a sixth expansion cabin body (43), one side of the vertical direction of the fourth cabin body (41) is provided with the fifth expansion cabin body (42), the other side of the vertical direction of the fourth cabin body (41) is provided with the sixth expansion cabin body (43), one side of a bottom plate of the fourth cabin body (41) close to the second cabin body (21) is provided with a fourth connecting plate (44), the surface of the fourth connecting plate (44) is uniformly provided with a bolt hole, one side of a bulkhead of the fourth cabin body (41) close to the second cabin body (21) is provided with a fourth sliding door (45), the middle part of the bottom plate in the fourth cabin body (41) is horizontally provided with a fifth sliding rail (46), the middle part of the bottom plate in the fourth cabin body (41) is vertically provided with a sixth sliding rail (47), the fifth sliding rail (46) and the middle part of the sixth sliding rail (47) are provided with a third sliding groove (48), and the third sliding groove (48) is arranged at the top end of the bottom plate in the fourth cabin body (41), and the third sliding base (48) is provided with a third sliding groove (49), and the third sliding base (48) is used for sliding; an eighth sliding rail (410) is arranged in the middle of the inner bottom plate of the sixth expansion cabin body (43) in the vertical direction;

when the sixth expansion cabin (43) is expanded, one end of the eighth sliding rail (410) is connected with one end of the sixth sliding rail (47).

5. The rapid deployment combined type composite surgical platform according to claim 1, wherein the connecting device (5) comprises a connecting frame (51), a connecting plate (52) and a fourth sliding groove (53), bolt holes are symmetrically formed in two sides of the connecting frame (51), the connecting plate (52) is mounted at the top end of the connecting frame (51), and the fourth sliding groove (53) is formed in the top end of the connecting plate (52).

6. The rapid deployment combined type composite surgical platform according to claim 4, wherein the first moving base (27), the second moving base (39) and the third moving base (49) comprise a bottom fixing base (61), a sliding block (62), a pulley (63) and a foot brake (64), the sliding block (62) is installed in the middle of the bottom end of the bottom fixing base (61), the pulley (63) is symmetrically installed at the two sides of the bottom end of the bottom fixing base (61), and the foot brake (64) is arranged in the middle of the pulley (63).

7. The rapid deployable composite surgical platform of claim 6, wherein the pulley (63) is a universal wheel.

8. The rapid deployable combined type composite surgical platform of claim 4, wherein the surfaces of the first slide rail (24), the second slide rail (25), the third slide rail (36), the fourth slide rail (37), the fifth slide rail (46) and the sixth slide rail (47) are provided with anti-skid patterns.

9. The rapid deployable composite surgical platform of claim 1, wherein the operating room shelter (1) comprises an operating bed (15), a medical tower crane, a ventilator, a monitor, a syringe pump, a display screen, and an operating light.

10. The rapid-deployment combined type composite surgical platform according to claim 4, wherein the walls of the first expansion cabin (12), the second expansion cabin (22), the third expansion cabin (32), the fourth expansion cabin (33), the fifth expansion cabin (42) and the sixth expansion cabin (43) are provided with door frames, and one side of each door frame is connected with a door through a hinge.

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