CN220014917U - Magnetic suspension translation door of sub-hyperbaric oxygen chamber - Google Patents

Abstract

The utility model discloses a magnetic suspension translation door of a sub-hyperbaric oxygen chamber, and relates to the technical field of sub-hyperbaric oxygen chambers, which are called micro-hyperbaric oxygen chambers. The magnetic suspension type door comprises a cabin body, wherein a door frame is fixedly installed at the position, close to the left side, of the front side of the cabin body, a first driving mechanism is installed at the position, close to the upper side, of the front side wall of the left door frame and the right door frame, a magnetic suspension rail is fixedly installed between the rear side of the first driving mechanism, a magnetic suspension driving assembly is movably installed on the magnetic suspension rail, a second driving mechanism is fixedly installed at the position, close to the lower side, of the front side wall of the door frame, a guide mechanism is installed between the second driving mechanisms, and a door plate is fixedly installed between the upper surface of the guide mechanism and the lower surface of the magnetic suspension driving assembly. The utility model realizes the automatic opening and closing of the door plate, reduces the friction in the moving process of the door plate, reduces the noise, does not cause noise to other patients when the door plate is opened and closed, ensures that the door plate is more tightly closed, has good sealing effect, increases the cleaning function of the observation window, and is beneficial to viewing the condition in the cabin by medical care.

Description

Magnetic suspension translation door of sub-hyperbaric oxygen chamber

Technical Field

The utility model relates to the technical field of sub-hyperbaric oxygen chambers, in particular to a magnetic suspension translation door of a sub-hyperbaric oxygen chamber.

Background

The sub-hyperbaric oxygen chamber is equipment widely applied in the medical treatment and health maintenance fields. Treatment of some diseases and alleviation of symptoms in patients are possible in the field of disease treatment; can be used for improving sub-health states such as fatigue, insomnia, headache, dizziness and the like in the medical care field, and has good health care and health preserving effects. The existing hyperbaric oxygen chamber mainly comprises a chamber body, a chamber door and an oxygen supply system, oxygen is supplied to the chamber body through the oxygen supply system, an inlet and an outlet are arranged on the chamber body for oxygen inhalation personnel to enter and exit, the inlet and the outlet are closed through the chamber door to prevent leakage of oxygen in the chamber body, the high-pressure state in the chamber body is maintained, and a relatively airtight space is formed in the chamber body after the chamber door is closed, so that oxygen inhalation effectiveness is ensured.

In the prior art, traditional sub-hyperbaric oxygen cabin adopts vertical hinged door more, in order to improve sealing performance simultaneously, the door is more thick, and manual opening and closing needs to consume great strength, is unfavorable for old and young use, simultaneously at the in-process of closing the door, can produce great noise, causes the influence to other patients in the sub-hyperbaric oxygen cabin, and sealed existence effect is not good simultaneously, and at the in-process of using, medical personnel need know the inside condition through the observation window on the hatch door, but, receive the inside humiture of sub-hyperbaric oxygen cabin etc. influence, can cause the inside fog of observation window, be unfavorable for observing the use.

Disclosure of Invention

The utility model provides a magnetic suspension sliding door of a sub-hyperbaric oxygen chamber, which aims to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a inferior hyperbaric oxygen cabin magnetic suspension translation door, includes the cabin body, the equal fixed mounting in position has the door frame about the leading flank of the cabin body is close to, and the leading flank of controlling the door frame is close to the upside position and install first actuating mechanism, and fixed mounting has the magnetic suspension track between the first actuating mechanism trailing flank, movable mounting has the magnetic suspension actuating assembly on the magnetic suspension track, the leading flank of door frame is close to the equal fixed mounting in downside position and has the second actuating mechanism, install guiding mechanism between the second actuating mechanism, fixed mounting has the door plant between guiding mechanism upper surface and the magnetic suspension actuating assembly lower surface, rubber seal is installed to the trailing flank of door plant, be close to upside position fixed mounting on the door plant has the observation window, cleaning mechanism is installed to the door plant leading flank that the observation window corresponds, cleaning mechanism includes electronic sharp module and sponge subassembly, electronic sharp module fixed mounting is in door plant leading flank, the slip table lower surface mounting of electronic sharp module has the sponge subassembly, and sponge subassembly trailing flank is laminated mutually with the observation window leading flank.

Further, the door frame is of a rectangular box structure, and the opposite side surfaces of the left door frame and the right door frame are of an opening structure.

Further, the first actuating mechanism includes electric telescopic handle, mounting panel and trigger switch, electric telescopic handle installs on the preceding lateral wall of door frame, electric telescopic handle's piston trailing flank passes through mounting panel and magnetic levitation track's leading flank fixed connection, trigger switch fixed mounting is in the corresponding right side door frame left surface of magnetic levitation drive assembly.

Further, the second driving mechanism and the first driving mechanism have the same structure, and the second driving mechanism and the first driving mechanism have a synchronous structure.

Further, the guide mechanism comprises a guide rail and a sliding block, the guide rail is arranged on the rear side face of the second driving mechanism, the sliding block is movably arranged on the guide rail, and the upper surface of the sliding block is fixedly connected with the upper surface of the door plate.

Furthermore, anti-collision sensors are uniformly arranged on the opposite side surfaces of the door frame, and a controller is arranged on the left side surface of the door frame.

Compared with the prior art, the utility model provides the magnetic suspension translation door of the sub-hyperbaric oxygen chamber, which has the following beneficial effects:

1. this inferior hyperbaric oxygen cabin magnetic suspension translation door makes magnetic suspension drive assembly drive the door plant and controls the removal through setting up the controller on the magnetic suspension track, realizes opening and close of door plant automatically, and reduces the friction of door plant removal process, noise reduction, can not cause the noise to other patients when the door plant is opened and close, and first actuating mechanism makes rubber seal and cabin inner wall laminating on the door plant simultaneously with second actuating mechanism, makes the door plant be closed inseparabler, and sealed effectual effectively avoids gas leakage.

2. This sub-hyperbaric oxygen cabin magnetic suspension translation door increases the clearance function to the observation window through setting up clearance mechanism, makes the observation window can not fog or be infected with the pollutant, does benefit to medical personnel to look over the internal condition of cabin.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a left side view of the door frame of the present utility model;

fig. 3 is a schematic rear view of a door panel of the present utility model.

In the figure: 1. a cabin body; 2. a door frame; 3. a first driving mechanism; 301. an electric telescopic rod; 302. a mounting plate; 303. triggering a switch; 4. a magnetic levitation track; 5. a magnetic levitation driving assembly; 6. a second driving mechanism; 7. a guide mechanism; 701. a guide rail; 702. a slide block; 8. a door panel; 9. a rubber seal ring; 10. an observation window; 11. a cleaning mechanism; 111. an electric linear module; 112. a sponge component; 12. an anti-collision sensor; 13. and a controller.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. 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.

Referring to fig. 1-3, the utility model discloses a magnetic suspension translation door of a sub-hyperbaric oxygen chamber, which comprises a chamber body 1, wherein a door frame 2 is fixedly installed at the position, close to the left side, of the front side surface of the chamber body 1, a first driving mechanism 3 is installed at the position, close to the upper side, of the front side wall of the left and right door frames 2, a magnetic suspension track 4 is fixedly installed between the rear side surfaces of the first driving mechanisms 3, a magnetic suspension driving assembly 5 is movably installed on the magnetic suspension track 4, a second driving mechanism 6 is fixedly installed at the position, close to the lower side, of the front side wall of the door frame 2, a guide mechanism 7 is installed between the second driving mechanism 6, a door plate 8 is fixedly installed between the upper surface of the guide mechanism 7 and the lower surface of the magnetic suspension driving assembly 5, a rubber sealing ring 9 is installed at the rear side surface of the door plate 8, an observation window 10 is fixedly installed at the position, a cleaning mechanism 11 is installed at the front side surface of the door plate 8 corresponding to the observation window 10, the cleaning mechanism 11 comprises an electric linear module 111 and a sponge assembly 112, the electric linear module 111 is fixedly installed on the front side wall of the door plate 8, a guide mechanism 7 is fixedly installed on the front side surface of the door plate 111, a lower side surface of the sponge assembly is close to the sponge assembly 112, a rectangular surface of the sponge assembly is installed on the lower surface of the sponge assembly is installed on the sponge assembly 112, and the sponge assembly is convenient to detach and install and detach.

Specifically, the door frame 2 has a rectangular box structure, and the opposite sides of the left and right door frames 2 have an opening structure.

In this embodiment, the door frame 2 is more firm in structure, and is less prone to deformation and damage.

Specifically, the first driving mechanism 3 includes an electric telescopic rod 301, a mounting plate 302 and a trigger switch 303, the electric telescopic rod 301 is mounted on the front side wall of the door frame 2, the rear side surface of the piston of the electric telescopic rod 301 is fixedly connected with the front side surface of the magnetic levitation track 4 through the mounting plate 302, and the trigger switch 303 is fixedly mounted on the left side surface of the corresponding right door frame 2 of the magnetic levitation driving assembly 5.

In this embodiment, the piston of the electric telescopic rod 301 drives the magnetic levitation track 4 to move back and forth through the mounting plate 302, that is, the magnetic levitation driving assembly 5 drives the door plate 8 to move left and right.

Specifically, the second driving mechanism 6 has the same structure as the first driving mechanism 3, and the second driving mechanism 6 and the first driving mechanism 3 have a synchronous structure.

In this embodiment, the second driving mechanism 6 and the first driving mechanism 3 synchronously drive the guiding mechanism 7 to move back and forth.

Specifically, the guide mechanism 7 includes a guide rail 701 and a slider 702, the guide rail 701 is mounted on the rear side surface of the second driving mechanism 6, the slider 702 is movably mounted on the guide rail 701, and the upper surface of the slider 702 is fixedly connected with the upper surface of the door panel 8.

In this embodiment, the slider 702 moves left and right on the guide rail 701 along with the door panel 8, and the slider 702 is normally in a non-contact state with the guide rail 701.

Specifically, the anti-collision sensors 12 are uniformly installed on the opposite sides of the door frame 2, and the controller 13 is installed on the left side of the door frame 2.

In this embodiment, when the left and right anti-collision sensors 12 are shielded, it is indicated that there are pedestrians or objects, information is fed back to the controller 13, and the controller 13 stops the magnetic levitation driving assembly 5 from driving the door panel 8 to move, so as to avoid collision in the left and right movement process of the door panel 8.

When the device is used, the magnetic levitation driving assembly 5 is driven to move left and right on the magnetic levitation track 4 through the controller 13, meanwhile, the lower end of the door plate 8 moves left and right along the guide rail 701 through the sliding block 702 in the guide mechanism 7, the door plate 8 is automatically opened and closed in the process of moving left and right, when the door plate 8 needs to be closed, the magnetic levitation driving assembly 5 drives the door plate 8 to move right, when the magnetic levitation driving assembly 5 is contacted with the trigger switch 303 in the first driving mechanism 3, the magnetic levitation driving assembly 5 stops moving, the electric telescopic rod 301 piston in the first driving mechanism 3 drives the magnetic levitation track 4 to move back and forth through the mounting plate 302, the magnetic levitation track 4 drives the door plate 8 to move back through the magnetic levitation driving assembly 5, the second driving mechanism 6 drives the lower side of the door plate 8 to move back through the guide mechanism 7, the rubber sealing ring 9 on the rear side of the door plate 8 seals the periphery inner wall of the upper door of the cabin 1, friction in the process of the door plate 8 is reduced, noise is reduced, the door plate 8 cannot be closed to other patients, the sealing effect is good, the situation that the magnetic levitation driving assembly is not polluted by the sponge window is driven by the electric linear assembly 111 in the cleaning mechanism 11, the sliding table is not polluted by the sponge window is driven by the sponge window 112, and the inner wall of the observation window is not polluted by the observation window 10, and the observation window is not cleaned by the observation window 1, and the observation window is polluted by the observation window is observed by the observation window 1.

To sum up, this inferior hyperbaric oxygen cabin magnetic suspension translation door realizes the automatic start and stop of door plant 8, and reduces the friction of door plant 8 removal process, noise reduction, can not cause the noise to other patients when door plant 8 opens and close, makes door plant 8 closed inseparabler, and sealed effectual increases the clearance function to observation window 10, does benefit to medical personnel to look over the condition in the cabin body 1.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a sub-hyperbaric oxygen cabin magnetic suspension translation door, includes the cabin body (1), its characterized in that: the utility model discloses a device for cleaning sponge, including cabin body (1), door frame (2) is all fixed mounting in the front side of cabin body (1) near controlling the position, and the front side wall of controlling door frame (2) is close to upside position and installs first actuating mechanism (3), and fixed mounting has magnetic suspension track (4) between first actuating mechanism (3) trailing flank, movable mounting has magnetic suspension actuating mechanism (5) on magnetic suspension track (4), the front side wall of door frame (2) is close to downside position and all fixed mounting has second actuating mechanism (6), install guiding mechanism (7) between second actuating mechanism (6), fixed mounting has door plant (8) between guiding mechanism (7) upper surface and magnetic suspension actuating mechanism (5) lower surface, rubber seal (9) are installed to the trailing flank of door plant (8), be close to upside position fixed mounting on door plant (8) has observation window (10), clearance mechanism (11) are installed to the front side of door plant (8) corresponding to observation window (10), clearance mechanism (11) include electronic sharp module (111) and sponge subassembly (112), electronic sharp module (111) are installed in the front side wall (111), and the back side of the sponge component (112) is attached to the front side of the observation window (10).

2. The sub-hyperbaric oxygen chamber magnetic levitation translation door of claim 1, wherein: the door frame (2) is of a rectangular box structure, and the opposite side surfaces of the left door frame (2) and the right door frame (2) are of an opening structure.

3. The sub-hyperbaric oxygen chamber magnetic levitation translation door of claim 1, wherein: the first driving mechanism (3) comprises an electric telescopic rod (301), a mounting plate (302) and a trigger switch (303), wherein the electric telescopic rod (301) is mounted on the front side wall of the door frame (2), the rear side face of a piston of the electric telescopic rod (301) is fixedly connected with the front side face of the magnetic suspension track (4) through the mounting plate (302), and the trigger switch (303) is fixedly mounted on the left side face of the right door frame (2) corresponding to the magnetic suspension driving assembly (5).

4. The sub-hyperbaric oxygen chamber magnetic levitation translation door of claim 1, wherein: the second driving mechanism (6) has the same structure as the first driving mechanism (3), and the second driving mechanism (6) and the first driving mechanism (3) have synchronous structures.

5. The sub-hyperbaric oxygen chamber magnetic levitation translation door of claim 1, wherein: the guide mechanism (7) comprises a guide rail (701) and a sliding block (702), the guide rail (701) is arranged on the rear side face of the second driving mechanism (6), the sliding block (702) is movably arranged on the guide rail (701), and the upper surface of the sliding block (702) is fixedly connected with the upper surface of the door plate (8).

6. The sub-hyperbaric oxygen chamber magnetic levitation translation door of claim 1, wherein: anti-collision sensors (12) are uniformly arranged on the opposite side surfaces of the door frame (2), and a controller (13) is arranged on the left side surface of the door frame (2).