CN112869515B - Auxiliary epidemic prevention clothing removing device - Google Patents

Abstract

The invention relates to an auxiliary epidemic prevention clothes removing device, belonging to the technical field of medical machinery, wherein a vertical column component I and a vertical column component II are symmetrically arranged about an a-a central line, a cross beam is fixedly connected to the upper ends of two shells of two vertical column components, the lower ends of the two shells are fixedly connected to a bottom plate, central threaded holes of two sliding blocks in two sliding block components are in threaded connection with two lead screws of the two vertical column components, four linear bearings fixedly connected to the two sliding blocks are respectively in sliding connection with four polished rods of the two vertical column components, the two lead screws are respectively driven by two motors, the outer side surfaces of two supporting arms in two rotating arm components are respectively fixedly connected to the inner surfaces of the two sliding blocks in the two sliding block components, a sterilizing lamp is fixedly connected below the cross beam, a remote control switch is fixedly connected to the rear middle part of the shell II in the vertical column component II, and two sensing lamps are respectively fixedly connected to the front middle parts of the two shells in the two vertical column components. The device can assist personnel to take off epidemic prevention clothes, and reduce the risk of personnel infection to the greatest extent.

Description

Auxiliary epidemic prevention clothing removing device

Technical Field

The invention belongs to the technical field of biomedical appliances, and particularly relates to an auxiliary epidemic prevention suit removing device.

Background

Epidemic prevention clothing refers to clothing that prevents medical personnel from being infected by pathogenic microorganisms or their carriers, and is typically worn in an epidemic area or contaminated area where the vector is present. At present, most epidemic prevention clothes are connected, namely, a head cover, a coat and trousers are connected into a whole, and an opening is formed in the front chest.

For areas with serious pollution, epidemic prevention clothes can carry a large number of pathogens after being used, and when workers take off the epidemic prevention clothes, if the workers do not operate properly, for example, skin directly contacts the epidemic prevention clothes, the probability of being infected can be greatly increased.

Disclosure of Invention

The invention aims to provide a device for assisting workers in removing epidemic prevention clothes.

The auxiliary epidemic prevention clothes removing device comprises a stand column component IA, a stand column component IIB, a slide block component IC, a slide block component IIE, a rotating arm component D, a bottom plate 1, a cross beam 2, a sterilizing lamp 3, a remote control switch 4, an induction lamp I5 a and an induction lamp II 5B, wherein the left end of the cross beam 2 is fixedly connected with the upper end of a shell I19 a in the stand column component IA, and the lower end of the shell I19 a is fixedly connected with the upper surface of the near left end of the bottom plate 1; the right end of the cross beam 2 is fixedly connected with the upper end of a shell II 19B in the upright post component II B, and the lower end of the shell II 19B is fixedly connected with the upper surface of the near right end of the bottom plate 1; the sterilizing lamp 3 is fixedly connected below the cross beam 2 and is arranged between the shell I19 a in the upright post assembly IA and the shell II 19B in the upright post assembly IIB; the remote control switch 4 is fixedly connected to the middle part of the rear of the shell II 19B in the upright post assembly IIB; the induction lamp I5 a is fixedly connected to the front middle part of the shell I19 a in the upright post assembly IA; the induction lamp II 5B is fixedly connected to the front middle part of the shell II 19B in the upright post assembly II B; the central threaded hole I26 a of the sliding block I22 a in the sliding block component IC is in threaded connection with the screw rod I18 a of the upright post component IA; the central threaded hole II 26B of the sliding block II 22B in the sliding block assembly II E is in threaded connection with the screw rod II 18B of the upright post assembly II B; the center of a linear bearing I21 a in the sliding block assembly IC is in sliding connection with a polish rod I11 a of the upright post assembly IA, and the center of a linear bearing II 23a is in sliding connection with a polish rod II 17a of the upright post assembly IA; the center of a linear bearing III 21B in the sliding block assembly II E is in sliding connection with a polish rod III 11B of the upright post assembly II B, and the center of a linear bearing IV 23B is in sliding connection with a polish rod IV 17B of the upright post assembly II B; the left side of a supporting arm II 34 in the rotating arm assembly D is fixedly connected to the right side of a sliding block I22 a in the sliding block assembly IC; the right side of the supporting arm I29 in the rotating arm assembly D is fixedly connected to the left side of the sliding block II 22b in the sliding block assembly II E.

The upright post component IA and the upright post component IIB are of the same structure and opposite in direction, and are symmetrically arranged about the central line of a-a, wherein the upright post component IA consists of a base 6, a motor I8 a, a flat plate 9, a coupler 10, a polished rod I11 a, a bearing 13, a top plate 16, a polished rod II 17a, a lead screw I18 a and a shell I19 a, and a left blind hole I7 and a right blind hole II 20 are formed in the flat plate 9; the top plate 16 is provided with a left blind hole II 12, a middle blind hole 14 and a right blind hole I15; the base 6 is fixedly connected to the lower end of the shell 19, and the top plate 16 is fixedly connected to the upper end of the shell 19; the bottom surface of a motor I8 a is fixedly connected to the upper surface of a base 6, a flat plate 9 is fixedly connected to the upper surface of the motor I8 a, the output end of the motor I8 a passes through the center of the flat plate 9 and is connected with the lower end of a lead screw I18 a through a coupler 10, and the upper end of the lead screw I18 a is movably connected with a middle blind hole 14 through a bearing 13; the lower end of the polish rod I11 a is fixedly connected with the left blind hole I7, the upper end of the polish rod I11 a is fixedly connected with the left blind hole II 12, the lower end of the polish rod II 17a is fixedly connected with the right blind hole II 20, and the upper end of the polish rod II 17a is fixedly connected with the right blind hole I15; the parts of the column assembly IIB corresponding to the motor I8 a, the polish rod I11 a, the polish rod II 17a, the lead screw I18 a and the shell I19 a in the column assembly IA are respectively a motor IV 8B, a polish rod III 11B, a polish rod IV 17B, a lead screw II 18B and a shell II 19B.

The sliding block component IC and the sliding block component IIE are of the same structure and opposite in direction, wherein the sliding block component IC consists of a linear bearing I21 a, a sliding block I22 a and a linear bearing II 23a, a rear through hole I25 a, a central threaded hole I26 a and a front through hole I27 a are formed in the sliding block I22 a, the linear bearing I21 a is fixedly connected with the rear through hole I25 a, and the linear bearing II 23a is fixedly connected with the front through hole I27 a; the sliding block component II E consists of a linear bearing III 21b, a sliding block II 22b and a linear bearing IV 23b, wherein a rear through hole II 25b, a central threaded hole II 26b and a front through hole II 27b are arranged on the sliding block II 22b, the linear bearing III 21b is fixedly connected with the rear through hole II 25b, and the linear bearing IV 23b is fixedly connected with the front through hole II 27b; the lower ends of the linear bearing I21 a, the linear bearing II 23a, the linear bearing III 21b and the linear bearing IV 23b are respectively provided with a flange plate 24.

The rotating arm assembly D consists of a rotating arm I28, a supporting arm I29, a motor II 30, an optical axis 31, a rear fork I32, a rear fork II 33, a supporting arm II 34, a motor III 35, a rotating arm II 36, a front fork I37 and a front fork II 38, wherein a through hole I39 a is formed in the right end of the rotating arm I28, and a hole pair I40 a is formed in the front end of the supporting arm I29; the left end of the rotary arm II 36 is provided with a through hole II 39b, and the front end of the support arm II 34 is provided with a hole pair II 40b; the front fork I37, the front fork II 38, the rotary arm I28, the support arm I29, the optical axis 31, the support arm II 34 and the rotary arm II 36 are sequentially arranged to form an open ring shape; the left end of the rotary arm I28 is fixedly connected with a front fork II 38, and the right end of the rotary arm I28 is movably connected with the front end of the support arm I29 through an output shaft of the motor II 30; the right end of the optical axis 31 is fixedly connected with the left end of the supporting arm I29, and the left end of the optical axis 31 is fixedly connected with the right end of the supporting arm II 34; the right end of the rotary arm II 36 is fixedly connected with a front fork I37, and the left end of the rotary arm II 36 is movably connected with the front end of the support arm II 34 through an output shaft of a motor III 35; the motor II 30 is fixedly connected to the front end of the supporting arm I29; the motor III 35 is fixedly connected to the front end of the support arm II 34; the rear fork I32 and the rear fork II 33 are fixedly connected to the middle part of the optical axis 31.

The working process of the invention is as follows:

When personnel do not enter the device, the sliding block component IC, the rotating arm component D and the sliding block component II E are at the highest position, and the sterilizing lamp 3 is also in a closed state; after the personnel wearing epidemic prevention clothes face to enter the device in the directions of the front fork I37 and the front fork II 38, the head cover is taken off, and after the remote control switch 4 receives external signals, the device starts to work: the motor I8 a and the motor IV 8B in the upright column assembly IA and the upright column assembly IIB drive the screw rod 18a and the screw rod II 18B to start rotating, and as the slide block assembly IC and the slide block assembly IIE are matched with the slide block I22 a and the central threaded hole I26 a and the central threaded hole II 26B of the slide block II 22B and the screw rod I18 a and the screw rod II 18B, the slide block assembly IC, the rotating arm assembly D and the slide block assembly II E move downwards along the axes of the screw rod I18 a and the screw rod II 18B, and during the movement, the rear fork I32 and the rear fork II 33 hook the head cover of the epidemic prevention suit at first, at the moment, the personnel wearing the epidemic prevention suit need to slightly shake the body, and the rear fork I32 and the rear fork II 33 continue to move downwards, so that the upper body of the epidemic prevention suit is removed; when the sliding block component IC, the rotating arm component D and the sliding block component II E descend to the waist position of a person, the induction lamp I5 a and the induction lamp II 5B are lightened and send signals to the motor I8 a and the motor IV 8B of the upright post component IA and the upright post component II B, so that the operation is suspended for a plurality of seconds, the sliding block component IC, the rotating arm component D and the sliding block component II E stop descending, and at the moment, the person needs to ensure that the lower body is hooked by the front fork I37 and the front fork II 38; the motor I8 a and the motor IV 8B continue to work after a few seconds, namely the sliding block component IC, the rotating arm component D and the sliding block component II E continue to move downwards along the axes of the lead screw I18 a and the lead screw II 18B, meanwhile, the motor II 30 and the motor III 35 start to work so as to drive the rotating arm I28 and the rotating arm II 36 to rotate outwards, in the process, people need to lift the feet by matching with the device, and when the sliding block component IC, the rotating arm component D and the sliding block component II E descend to the lowest position, the motor I8 a and the motor IV 8B of the upright post component IA and the upright post component II B stop rotating, and epidemic prevention clothes are separated from the staff, and the personnel leave the device; the remote control switch 4 receives external signals again, the sterilizing lamp 3 is turned off, the motor I8 a and the motor IV 8B of the upright post component IA and the upright post component IIB reversely rotate, and then the sliding block component IC, the rotating arm component D and the sliding block component IIE are driven to move upwards along the axes of the screw rod 18a and the screw rod II 18B until the highest position, so that the whole working flow of the device is completed.

The auxiliary epidemic prevention clothes removing device can assist workers to remove epidemic prevention clothes, so that the workers are prevented from directly contacting the used epidemic prevention clothes to the greatest extent, and the infection risk of first-line medical workers is greatly reduced.

Drawings

FIG. 1 is a rear perspective view of an auxiliary desquamation epidemic prevention suit device

FIG. 2 is a front perspective view of an auxiliary epidemic prevention suit removal device

FIG. 3 is a rear view of the auxiliary desquamation anti-epidemic device

FIG. 4 is a front view of a column assembly IA

FIG. 5 is a front view of column assembly IIB

FIG. 6 is an isometric view of a slider assembly IC

FIG. 7 is an isometric view of a slider assembly IIE

FIG. 8 is an isometric view of a linear bearing I21 a

FIG. 9 is an isometric view of slider I22 a

FIG. 10 is an isometric view of a slider II 22b

Fig. 11 is an isometric view of a rotary arm assembly D

FIG. 12 is an isometric view of the rotating arm I28

FIG. 13 is an isometric view of a rotating arm II 36

Fig. 14 is an isometric view of support arm i 29

FIG. 15 is an isometric view of support arm II 34

Wherein: A. column assembly IB, column assembly IIC, slider assembly ID, rotary arm assembly E, slider assembly II 1, bottom plate 2, cross beam 3, germicidal lamp 4, remote switch 5a, induction lamp I5 b, induction lamp II 6, base 7, left blind hole I8 a, motor I8 b, motor IV 9, plate 10, coupling 11a, polish rod I11 b, polish rod III 12, left blind hole II 13, bearing 14, middle blind hole 15, right blind hole I16, top plate 17a, polish rod II 17b, polish rod IV 18a, lead screw I18 b, lead screw II 19a, housing I19 b, housing II 20, right blind hole III 12. II 21a, linear bearing I21 b, linear bearing III 22a, slide I22 b, slide II 23a, linear bearing II 23b, linear bearing IV 24, flange 25a, rear through hole I25 b, rear through hole II 26a, central threaded hole I26 b, central threaded hole II 27a, front through hole I27 b, front through hole II 28, rotating arm I29, support arm I30, motor II 31, optical axis 32, rear fork I33, rear fork II 34, slider II 35, motor III 36, rotating arm II 37, front fork I38, front fork II 39a, through hole I39 b, through hole II

40A, hole pair I40 b, hole pair II

Detailed Description

The invention is described below with reference to the accompanying drawings.

As shown in fig. 1 and 2, the auxiliary epidemic prevention removing clothing device of the invention comprises a column component ia, a column component ib, a slide block component ic, a slide block component ie, a rotating arm component D, a base plate 1, a beam 2, a sterilizing lamp 3, a remote control switch 4, an induction lamp i 5a and an induction lamp ii 5B, wherein the left end of the beam 2 is fixedly connected with the upper end of a shell i 19a in the column component ia, and the lower end of the shell i 19a is fixedly connected with the upper surface of the near left end of the base plate 1; the right end of the cross beam 2 is fixedly connected with the upper end of a shell II 19B in the upright post component II B, and the lower end of the shell II 19B is fixedly connected with the upper surface of the near right end of the bottom plate 1; the sterilizing lamp 3 is fixedly connected below the cross beam 2 and is arranged between the shell I19 a in the upright post assembly IA and the shell II 19B in the upright post assembly IIB; the remote control switch 4 is fixedly connected to the middle part of the rear of the shell II 19B in the upright post assembly IIB; the induction lamp I5 a is fixedly connected to the front middle part of the shell I19 a in the upright post assembly IA; the induction lamp II 5B is fixedly connected to the front middle part of the shell II 19B in the upright post assembly II B; the central threaded hole I26 a of the sliding block I22 a in the sliding block component IC is in threaded connection with the screw rod I18 a of the upright post component IA; the central threaded hole II 26B of the sliding block II 22B in the sliding block assembly II E is in threaded connection with the screw rod II 18B of the upright post assembly II B; the center of a linear bearing I21 a in the sliding block assembly IC is in sliding connection with a polish rod I11 a of the upright post assembly IA, and the center of a linear bearing II 23a is in sliding connection with a polish rod II 17a of the upright post assembly IA; the center of a linear bearing III 21B in the sliding block assembly II E is in sliding connection with a polish rod III 11B of the upright post assembly II B, and the center of a linear bearing IV 23B is in sliding connection with a polish rod IV 17B of the upright post assembly II B; the left side of a supporting arm II 34 in the rotating arm assembly D is fixedly connected to the right side of a sliding block I22 a in the sliding block assembly IC; the right side of the supporting arm I29 in the rotating arm assembly D is fixedly connected to the left side of the sliding block II 22b in the sliding block assembly II E.

As shown in fig. 3-5, the upright column assembly ia and the upright column assembly iib have the same structure, opposite directions and are symmetrically arranged about the a-a central line, wherein the upright column assembly ia consists of a base 6, a motor i 8a, a flat plate 9, a coupler 10, a polished rod i 11a, a bearing 13, a top plate 16, a polished rod ii 17a, a lead screw i 18a and a shell i 19a, and a left blind hole i 7 and a right blind hole ii 20 are formed in the flat plate 9; the top plate 16 is provided with a left blind hole II 12, a middle blind hole 14 and a right blind hole I15; the base 6 is fixedly connected to the lower end of the shell 19, and the top plate 16 is fixedly connected to the upper end of the shell 19; the bottom surface of a motor I8 a is fixedly connected to the upper surface of a base 6, a flat plate 9 is fixedly connected to the upper surface of the motor I8 a, the output end of the motor I8 a passes through the center of the flat plate 9 and is connected with the lower end of a lead screw I18 a through a coupler 10, and the upper end of the lead screw I18 a is movably connected with a middle blind hole 14 through a bearing 13; the lower end of the polish rod I11 a is fixedly connected with the left blind hole I7, the upper end of the polish rod I11 a is fixedly connected with the left blind hole II 12, the lower end of the polish rod II 17a is fixedly connected with the right blind hole II 20, and the upper end of the polish rod II 17a is fixedly connected with the right blind hole I15; the parts of the column assembly IIB corresponding to the motor I8 a, the polish rod I11 a, the polish rod II 17a, the lead screw I18 a and the shell I19 a in the column assembly IA are respectively a motor IV 8B, a polish rod III 11B, a polish rod IV 17B, a lead screw II 18B and a shell II 19B.

As shown in fig. 6-10, the sliding block component ic and the sliding block component ie have the same structure and opposite directions, wherein the sliding block component ic is composed of a linear bearing i 21a, a sliding block i 22a and a linear bearing ii 23a, the sliding block i 22a is provided with a rear through hole i 25a, a central threaded hole i 26a and a front through hole i 27a, the linear bearing i 21a is fixedly connected with the rear through hole i 25a, and the linear bearing ii 23a is fixedly connected with the front through hole i 27a; the sliding block component II E consists of a linear bearing III 21b, a sliding block II 22b and a linear bearing IV 23b, wherein a rear through hole II 25b, a central threaded hole II 26b and a front through hole II 27b are arranged on the sliding block II 22b, the linear bearing III 21b is fixedly connected with the rear through hole II 25b, and the linear bearing IV 23b is fixedly connected with the front through hole II 27b; the lower ends of the linear bearing I21 a, the linear bearing II 23a, the linear bearing III 21b and the linear bearing IV 23b are respectively provided with a flange plate 24.

As shown in fig. 11-15, the rotating arm assembly D is composed of a rotating arm i 28, a supporting arm i 29, a motor ii 30, an optical axis 31, a rear fork i 32, a rear fork ii 33, a supporting arm ii 34, a motor iii 35, a rotating arm ii 36, a front fork i 37, and a front fork ii 38, wherein a through hole i 39a is provided at the right end of the rotating arm i 28, and a hole pair i 40a is provided at the front end of the supporting arm i 29; the left end of the rotary arm II 36 is provided with a through hole II 39b, and the front end of the support arm II 34 is provided with a hole pair II 40b; the front fork I37, the front fork II 38, the rotary arm I28, the support arm I29, the optical axis 31, the support arm II 34 and the rotary arm II 36 are sequentially arranged to form an open ring shape; the left end of the rotary arm I28 is fixedly connected with a front fork II 38, and the right end of the rotary arm I28 is movably connected with the front end of the support arm I29 through an output shaft of the motor II 30; the right end of the optical axis 31 is fixedly connected with the left end of the supporting arm I29, and the left end of the optical axis 31 is fixedly connected with the right end of the supporting arm II 34; the right end of the rotary arm II 36 is fixedly connected with a front fork I37, and the left end of the rotary arm II 36 is movably connected with the front end of the support arm II 34 through an output shaft of a motor III 35; the motor II 30 is fixedly connected to the front end of the supporting arm I29; the motor III 35 is fixedly connected to the front end of the support arm II 34; the rear fork I32 and the rear fork II 33 are fixedly connected to the middle part of the optical axis 31.

Claims (3)

1. An auxiliary epidemic prevention clothes removing device is characterized in that: the novel multifunctional electric bicycle comprises a stand column assembly I (A), a stand column assembly II (B), a slide block assembly I (C), a slide block assembly II (E), a rotating arm assembly (D), a bottom plate (1), a cross beam (2), a sterilizing lamp (3), a remote control switch (4), an induction lamp I (5 a) and an induction lamp II (5B), wherein the rotating arm assembly (D) comprises a rotating arm I (28), a supporting arm I (29), a motor II (30), an optical axis (31), a rear fork I (32), a rear fork II (33), a supporting arm II (34), a motor III (35), a rotating arm II (36), a front fork I (37) and a front fork II (38), a through hole I (39 a) is formed in the right end of the rotating arm I (28), and a hole pair I (40 a) is formed in the front end of the supporting arm I (29); the left end of the rotary arm II (36) is provided with a through hole II (39 b), and the front end of the support arm II (34) is provided with a hole pair II (40 b); the front fork I (37), the front fork II (38), the rotating arm I (28), the supporting arm I (29), the optical axis (31), the supporting arm II (34) and the rotating arm II (36) are sequentially arranged to form an open ring shape; the left end of the rotary arm I (28) is fixedly connected with the front fork II (38), and the right end of the rotary arm I (28) is movably connected with the front end of the support arm I (29) through the output shaft of the motor II (30); the right end of the optical axis (31) is fixedly connected with the left end of the supporting arm I (29), and the left end of the optical axis (31) is fixedly connected with the right end of the supporting arm II (34); the right end of the rotary arm II (36) is fixedly connected with the front fork I (37), and the left end of the rotary arm II (36) is movably connected with the front end of the support arm II (34) through an output shaft of the motor III (35); the motor II (30) is fixedly connected to the front end of the supporting arm I (29); the motor III (35) is fixedly connected to the front end of the supporting arm II (34); the rear fork I (32) and the rear fork II (33) are fixedly connected to the middle part of the optical axis (31); the left end of the cross beam (2) is fixedly connected with the upper end of a shell I (19 a) in the upright post component I (A), and the lower end of the shell I (19 a) is fixedly connected with the upper surface of the near left end of the bottom plate (1); the right end of the cross beam (2) is fixedly connected with the upper end of a shell II (19B) in the upright post component II (B), and the lower end of the shell II (19B) is fixedly connected with the upper surface of the near right end of the bottom plate (1); the sterilizing lamp (3) is fixedly connected below the cross beam (2), and is arranged between a shell I (19 a) in the upright post assembly I (A) and a shell II (19B) in the upright post assembly II (B); the remote control switch (4) is fixedly connected to the middle part of the rear of the shell II (19B) in the upright post assembly II (B); the induction lamp I (5 a) is fixedly connected to the front middle part of the shell I (19 a) in the upright post component I (A); the induction lamp II (5B) is fixedly connected to the front middle part of the shell II (19B) in the upright post assembly II (B); the central threaded hole I (26 a) of the sliding block I (22 a) in the sliding block assembly I (C) is in threaded connection with the screw rod I (18 a) of the upright post assembly I (A); a central threaded hole II (26B) of a sliding block II (22B) in the sliding block assembly II (E) is in threaded connection with a screw rod II (18B) of the upright post assembly II (B); the center of a linear bearing I (21 a) in the sliding block assembly I (C) is in sliding connection with a polish rod I (11 a) of the upright post assembly I (A), and the center of a linear bearing II (23 a) is in sliding connection with a polish rod II (17 a) of the upright post assembly I (A); the center of a linear bearing III (21B) in the sliding block assembly II (E) is in sliding connection with a polished rod III (11B) of the upright post assembly II (B), and the center of a linear bearing IV (23B) is in sliding connection with a polished rod IV (17B) of the upright post assembly II (B); the left side of a supporting arm II (34) in the rotating arm assembly (D) is fixedly connected to the right side of a sliding block I (22 a) in the sliding block assembly I (C); the right side of a supporting arm I (29) in the rotating arm assembly (D) is fixedly connected to the left side of a sliding block II (22 b) in the sliding block assembly II (E).

2. The auxiliary de-epidemic prevention clothes apparatus according to claim 1, wherein: the vertical column assembly I (A) and the vertical column assembly II (B) are of the same structure and opposite in direction, and are symmetrically arranged about the central line of a-a, wherein the vertical column assembly I (A) consists of a base (6), a motor I (8 a), a flat plate (9), a coupler (10), a polished rod I (11 a), a bearing (13), a top plate (16), a polished rod II (17 a), a lead screw I (18 a) and a shell I (19 a), and a left blind hole I (7) and a right blind hole II (20) are formed in the flat plate (9); a left blind hole II (12), a middle blind hole (14) and a right blind hole I (15) are formed in the top plate (16); the base (6) is fixedly connected with the lower end of the shell (19), and the top plate (16) is fixedly connected with the upper end of the shell (19); the bottom surface of a motor I (8 a) is fixedly connected to the upper surface of a base (6), a flat plate (9) is fixedly connected to the upper surface of the motor I (8 a), the output end of the motor I (8 a) passes through the center of the flat plate (9) and is connected with the lower end of a screw rod I (18 a) through a coupler (10), and the upper end of the screw rod I (18 a) is movably connected with a middle blind hole (14) through a bearing (13); the lower end of the polish rod I (11 a) is fixedly connected with the left blind hole I (7), the upper end of the polish rod I (11 a) is fixedly connected with the left blind hole II (12), the lower end of the polish rod II (17 a) is fixedly connected with the right blind hole II (20), and the upper end of the polish rod II (17 a) is fixedly connected with the right blind hole I (15); parts corresponding to the motor I (8 a), the polished rod I (11 a), the polished rod II (17 a), the lead screw I (18 a) and the shell I (19 a) in the upright post assembly II (B) are respectively a motor IV (8B), a polished rod III (11B), a polished rod IV (17B), a lead screw II (18B) and a shell II (19B).

3. The auxiliary de-epidemic prevention clothes apparatus according to claim 1, wherein: the sliding block assembly I (C) and the sliding block assembly II (E) are in the same structure and opposite in direction, wherein the sliding block assembly I (C) consists of a linear bearing I (21 a), a sliding block I (22 a) and a linear bearing II (23 a), a rear through hole I (25 a), a central threaded hole I (26 a) and a front through hole I (27 a) are formed in the sliding block I (22 a), the linear bearing I (21 a) is fixedly connected with the rear through hole I (25 a), and the linear bearing II (23 a) is fixedly connected with the front through hole I (27 a); the sliding block assembly II (E) consists of a linear bearing III (21 b), a sliding block II (22 b) and a linear bearing IV (23 b), wherein a rear through hole II (25 b), a central threaded hole II (26 b) and a front through hole II (27 b) are arranged on the sliding block II (22 b), the linear bearing III (21 b) is fixedly connected with the rear through hole II (25 b), and the linear bearing IV (23 b) is fixedly connected with the front through hole II (27 b); the lower ends of the linear bearing I (21 a), the linear bearing II (23 a), the linear bearing III (21 b) and the linear bearing IV (23 b) are respectively provided with a flange plate (24).