CN212020728U - Nosocomial infection detection management tool - Google Patents

Abstract

The application relates to the technical field of medical equipment, and particularly discloses a hospital infection detection management tool, which comprises a box body and a cover body, wherein a first partition plate is fixed on the inner side of the upper part of the box body, a whole block of heat insulation material is arranged on the first partition plate, a cylindrical groove is formed in the heat insulation material, and a first drawer, a second drawer, a third drawer and a fourth drawer are sequentially connected onto the part, positioned below the partition plate, in the box body in a sliding manner from top to bottom; one side of being connected with the box on the lid is fixed with the interior buckle plate with box oral area matched with, when the lid was in the box oral area, interior buckle plate interior knot got into in the box and with box interference fit. The purpose of this patent is to solve current infection detection toolbox and because of the storage space is little, the limitation is deposited to article, the medical instrument's of being not convenient for deposit, the problem that detection efficiency is low that leads to.

Description

Nosocomial infection detection management tool

Technical Field

The utility model relates to the technical field of medical equipment, in particular to infection detection management instrument in hospital.

Background

When carrying out hospital infection to each administrative or technical offices of hospital and detecting, testing personnel often need use the test tube, the culture dish and corresponding liquid medicine to go the scene and carry out the operation, because of the article of needs are more, the inconvenience of taking, and when carrying out the detection of whole hospital, required article are the increase at double more, have increased medical staff's the work degree of difficulty and operating pressure more, need one kind for this to carry out the toolbox that reasonable standard integrated with each instrument that is used for hospital infection to detect, but prior art: the tool box has small storage space, the storage of articles is limited, and tools in the tool box are inconvenient to take after being stored.

In addition, some medical solutions for infection detection require incubation to ensure efficacy.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art, the utility model provides a technical problem provides infection detection management instrument in hospital's institute, solves current infection detection toolbox and because of the storage space is little, and article deposit the limitation, the medical instrument of being not convenient for deposit, the detection efficiency that leads to is low problem.

In order to solve the above problem, the utility model discloses the technical scheme who adopts is: the hospital infection detection management tool comprises a box body and a cover body, wherein the box body is in a cuboid shape with an axis arranged along the vertical direction, a first partition plate arranged along the horizontal direction is fixed on the inner side of the upper part of the box body, a whole block of heat insulation material is arranged on the first partition plate, a cylindrical groove with an axis arranged along the vertical direction is formed in the heat insulation material, and a first drawer, a second drawer, a third drawer and a fourth drawer are sequentially connected onto the part, located below the partition plate, in the box body in a sliding mode from top to bottom; the drawer panels of the first drawer, the second drawer, the third drawer and the fourth drawer are respectively in one-to-one correspondence with one of the front side wall, the rear side wall, the left side wall and the right side wall of the box body and are parallel to each other; one side of being connected with the box on the lid is fixed with the interior buckle plate with box oral area matched with, when the lid was in the box oral area, interior buckle plate interior knot got into in the box and with box interference fit.

The technical principle of the technical scheme is as follows:

1. the box body is divided into an upper part and a lower part by a partition plate on the box body, the first partition plate is provided with a whole piece of heat insulation material, the heat insulation material is provided with a cylindrical groove of which the axis is arranged along the vertical direction, and a liquid medicine bottle is placed in the cylindrical groove to play a role in limiting and insulating the liquid medicine bottle, so that the efficacy of the liquid medicine is kept in a better state;

2. the first drawer, the second drawer, the third drawer and the fourth drawer are respectively used for storing test tubes, culture dishes, other detection tools, paper pens for recording and the like for detection. The purpose that makes the panel of first drawer, second drawer, third drawer and fourth drawer respectively with one-to-one in the four lateral walls of the front and back, left and right of box and be parallel to each other is when first drawer, second drawer, third drawer and fourth drawer roll-off from the box, do not shelter from each other between each drawer to conveniently take the inside detection instrument of drawer.

3. The cover body is arranged and is used for protecting and preserving the liquid medicine bottle.

The beneficial effect that this scheme produced is:

1. compared with the existing infection detection tool box, the existing infection detection tool box has low detection efficiency due to small storage space, limited article storage and inconvenience for storage of medical instruments; and through set up a first baffle and four drawers on the box in this application scheme to the convenient liquid medicine bottle, test tube, culture dish, other instruments that will infect the detection usefulness and the paper pen etc. that records deposit alone respectively, make things convenient for the storage and the management of detection instrument.

2. Compared with the existing infection detection tool box, the existing infection detection tool box has the defects that the taken infection monitoring tool is inconvenient to take due to the traditional structure; and the panel through making first drawer, second drawer, third drawer and fourth drawer in this application scheme respectively with the preceding, back, in the four lateral walls on a left side, the right side of box one-to-one and be parallel to each other to when following the roll-off of first drawer, second drawer, third drawer and fourth drawer on the box, each other does not shelter from between each drawer, conveniently takes the inside infection detection instrument of box.

3. Compared with the existing infection detection tool box, the existing infection detection tool box lacks a heat preservation device for the liquid medicine bottle, so that the liquid medicine for infection detection cannot keep the optimal temperature; and be used for holding the liquid medicine bottle through using the cylindric recess of foam preparation in this application scheme, join in marriage the lid again and protect and keep warm the liquid medicine bottle to can keep warm to the inside liquid medicine of liquid medicine bottle, thereby improve the precision of the school measuring result of infection detection.

Further, the inside first arch that is provided with the curved of cylinder recess, the effect of first arch is that the liquid medicine bottle that will put into the inside cylinder recess is spacing, avoids the in-process liquid medicine bottle of transportation to rock.

Further, one of the first drawer, the second drawer, the third drawer and the fourth drawer is provided with a cylindrical second protrusion with an axis arranged along the vertical direction at the inner bottom, and the height of the second protrusion is 0.3-1 cm.

The second bulge has the function of reversely buckling the culture dish on the second bulge, so that the phenomenon that the interior of the culture dish is polluted by falling ash or shakes in the transportation process is avoided.

Further, a second partition plate arranged in the vertical direction is fixed to the inner bottom of one of the first drawer, the second drawer, the third drawer and the fourth drawer. The second partition plate is used for partitioning the interior of the corresponding drawer, so that different infection detection tools can be placed in different areas.

Further, the inner bottom of one of the first drawer, the second drawer, the third drawer and the fourth drawer is fixed with a test tube rack made of a whole foam board, and the test tube rack is provided with a circular test tube hole with an axis arranged along the vertical direction.

The test tube rack is used for placing a test tube for infection detection, and the test tube is inserted into the test tube port in an inverted mode during placement.

Furthermore, the tops of two opposite side walls on the box body are respectively fixed with a strap. The box body is convenient to move by utilizing the straps.

Furthermore, wheels are fixed at the bottom of the box body, so that the box body is convenient to move.

Further, the upper end of the cover body is provided with a handle, so that the cover body can be conveniently opened and closed.

Furthermore, the parts of the side wall of the box body, which are positioned right above the first drawer, the second drawer, the third drawer and the fourth drawer, are respectively fixed with a rotating shaft, the axis of each rotating shaft is perpendicular to the side wall of the box body, each rotating shaft is rotatably connected with a limiting block, and the limiting blocks are vertically arranged downwards under the self gravity.

The limiting block is used for preventing the drawer from being limited in the transportation process and preventing the drawer from sliding out of the box body; during detection, the drawer can slide out of the box body by rotating the limiting block upwards to the horizontal position.

Drawings

Fig. 1 is a plan view of a cabinet when a drawer is fully opened.

Fig. 2 is a bottom view of the cover.

Fig. 3 is a front view of the cover.

Fig. 4 is a front view of the cabinet when the drawer is fully closed.

Fig. 5 is a right side view of the cabinet with the drawer fully closed.

Fig. 6 is a rear view of the cabinet with the drawer fully closed.

Fig. 7 is a left side view of the cabinet with the drawer fully closed.

Fig. 8 is a top view of the overall structure with the drawer fully closed.

Detailed Description

The following is further detailed by way of specific embodiments:

reference numerals in the drawings of the specification include: the multifunctional test tube rack comprises a box body 10, a first partition plate 11, a cylindrical groove 111, a first drawer 12, a second drawer 13, a second protrusion 131, a third drawer 14, a second partition plate 141, a fourth drawer 15, a test tube rack 151, test tube holes 152, braces 16, wheels 17, a cover body 20, an inner buckle plate 21, a handle 22, a rotating shaft 30 and a limiting block 31.

The embodiments are substantially as shown in figures 1 to 8 of the accompanying drawings: the hospital infection detection management tool comprises a box body 10 and a cover body 20.

As shown in fig. 1, the box 10 is shaped as a rectangular parallelepiped with an axis arranged in a vertical direction, a first partition plate 11 of a rectangular shape arranged in a horizontal direction is fixed on the inner side of the upper portion of the box 10, a whole block of heat insulating material is fixed on the first partition plate 11, the heat insulating material in this embodiment is a foam board, the size of the first partition plate 11 and the size of the whole block of heat insulating material are both equal to the size of the cross section of the box 10, a cylindrical groove 111 with an axis arranged in a vertical direction is formed in the heat insulating material, a first arc-shaped columnar bulge made of a foam material is fixed inside the cylindrical groove 111, the number of the first bulges is set to 6, and the first bulges are circumferentially and uniformly distributed on the inner side wall of the cylindrical groove; the number of the cylindrical grooves 111 is set to 4 and the grooves are symmetrically distributed on the whole piece of the heat preservation material.

As shown in FIG. 2, the cover 20 is a rectangular foam board with a shape and size corresponding to the cross section of the box 10, an inner fastening board 21 of rectangular foam material is fixed on the lower side of the cover 20 and matches with the mouth of the box 10, and when the cover 20 covers the mouth of the box 10, the inner fastening board 21 is fastened into the box 10 and is in interference fit with the box 10. The upper end of the cover body 20 is provided with a handle 22 for facilitating the opening and closing of the cover body 20.

The cylindrical groove is used for accommodating the liquid medicine bottle, so that the liquid medicine in the liquid medicine bottle can be kept warm, and the accuracy of the calibration result of infection detection is improved. The first protrusion is used for limiting the liquid medicine bottle placed in the cylindrical groove 111, and the liquid medicine bottle is prevented from shaking in the transportation process. The cover body 20 is used for protecting and insulating the liquid medicine bottle.

As shown in fig. 4-7, a first drawer 12 is slidably connected to a portion of the front side surface of the box body 10 below the partition, a drawer panel of the first drawer 12 is parallel to the front side surface of the box body 10, and a finger groove allowing a finger to extend into the drawer panel of the first drawer 12 is formed; a second drawer 13 is connected to the part, below the first drawer 12, of the right side surface of the box body 10 in a sliding mode, a drawer panel of the second drawer 13 is parallel to the right side surface of the box body 10, and a finger groove allowing a finger to extend into is formed in the drawer panel of the second drawer 13; a third drawer 14 is connected to the part of the rear side surface of the box body 10, which is positioned below the second drawer 13, in a sliding manner, a drawer panel of the third drawer 14 is parallel to the rear side surface of the box body 10, and a finger groove allowing a finger to extend into is also formed in the drawer panel of the third drawer 14; a fourth drawer 15 is connected to the part, located below the third drawer 14, on the left side face of the box body 10 in a sliding manner, a drawer panel of the fourth drawer 15 is parallel to the left side face of the box body 10, and a finger groove allowing a finger to extend into is also formed in the drawer panel of the fourth drawer 15; the first drawer 12, the second drawer 13, the third drawer 14 and the fourth drawer 15 are all connected with the box body 10 through slide rails, and the structure of the slide rails is the existing one.

As shown in fig. 1, the inner bottom of the second drawer 13 is provided with cylindrical second protrusions 131 made of foam material and having axes arranged in a vertical direction, the height of the second protrusions 131 is 0.3cm, and the number of the second protrusions 131 is 4 and the second protrusions are symmetrically distributed inside the second drawer 13.

The second protrusion 131 is used for reversely buckling the culture dish on the second protrusion 131, so that the interior of the culture dish is prevented from being polluted or shaking in the transportation process.

As shown in fig. 1, the inner bottom of the third drawer 14 is fixed with second partitions 141 arranged in the vertical direction, and the number of the second partitions 141 is set to 3 and evenly distributed at intervals at the inner bottom of the second drawer 13. The second partition 141 serves to partition the inside of the corresponding drawer, so that different infection detection tools can be divisionally placed.

As shown in fig. 1, a test tube rack 151 made of a whole foam board is fixed at the bottom of the fourth drawer 15, circular test tube holes 152 are formed in the test tube rack 151, the axes of the test tube holes are arranged in the vertical direction, and the number of the test tube holes 152 is set to 36 and the test tube holes are uniformly distributed in the fourth drawer 15.

The test tube rack 151 is used to hold a test tube for infection detection, and the test tube is inserted into the test tube port while being placed upside down.

As shown in fig. 1, a strap 16 is fixed to the top of each of the left and right side walls of the box 10. The carrying straps 16 facilitate movement of the enclosure 10.

As shown in FIG. 4, wheels 17 are fixed to the bottom of the case 10 to facilitate movement of the case 10.

As shown in fig. 4-7, a rotating shaft 30 is fixed on the outer side wall of the box 10 directly above the first drawer 12, the second drawer 13, the third drawer 14 and the fourth drawer 15, the axis of the rotating shaft 30 is perpendicular to the side of the box 10, a long-strip-shaped stop block 31 made of stainless steel is rotatably connected to each rotating shaft 30, one end of each stop block 31 is rotatably connected to the rotating shaft 30, the other end of each stop block 31 can rotate along the rotating shaft 30, and each stop block 31 is vertically arranged downward under the self gravity.

The limiting block 31 is used for preventing the drawer from being limited in the transportation process and preventing the drawer from sliding out of the box body 10; during detection, the drawer can slide out of the box body 10 by rotating the limiting block 31 upwards to the horizontal position.

Fig. 8 shows an overall structure in which 4 drawers are completely received in the case 10 and the cover 20 is placed on the case 10.

The specific implementation process is as follows:

all the drawers are opened, paper pens for recording are placed in the first drawer 12, a culture dish is placed in the second drawer 13, then the second drawer 13 is closed, other infection detection tools are placed in the third drawer 14, a test tube is placed in the fourth drawer 15, then the fourth drawer 15 is closed, the cover body 20 is opened, a liquid medicine bottle for infection detection is placed in the cylindrical groove, and then the cover body 20 is closed.

After the box 10 is moved to a predetermined place by the straps 16 and the wheels 17, all the drawers and the lid 20 are opened, and the corresponding tools for infection detection and the liquid medicine bottles are taken out for infection detection.

After the detection is completed, all the infection detection tools and the liquid medicine bottles are reset, the cover 20 and all the drawers are closed, and the box body 10 is moved to a designated place by the cooperation of the straps 16 and the wheels 17.

The above description is only an example of the present invention, and the common general knowledge of the known specific structures and characteristics of the embodiments is not described herein. It should be noted that, for those skilled in the art, without departing from the structure of the present invention, several modifications and improvements can be made, which should also be regarded as the protection scope of the present invention, and these will not affect the effect of the implementation of the present invention and the practicability of the patent. The scope of the claims of the present application shall be determined by the contents of the claims, and the description of the embodiments and the like in the specification shall be used to explain the contents of the claims.

Claims (9)

1. Nosocomial infection detection management instrument of hospital, its characterized in that: the box body is in a cuboid shape with an axis arranged along the vertical direction, a first partition plate arranged along the horizontal direction is fixed on the inner side of the upper part of the box body, a whole block of heat insulation material is arranged on the first partition plate, a cylindrical groove with an axis arranged along the vertical direction is formed in the heat insulation material, and a first drawer, a second drawer, a third drawer and a fourth drawer are sequentially connected onto the part, located below the partition plate, in the box body in a sliding mode from top to bottom; the drawer panels of the first drawer, the second drawer, the third drawer and the fourth drawer are respectively in one-to-one correspondence with one of the front side wall, the rear side wall, the left side wall and the right side wall of the box body and are parallel to each other; one side of being connected with the box on the lid is fixed with the interior buckle plate with box oral area matched with, when the lid was in the box oral area, interior buckle plate interior knot got into in the box and with box interference fit.

2. The hospital inpatient infection detection management tool of claim 1, wherein: the inside first arch that is provided with the curved of cylinder recess.

3. The hospital inpatient infection detection management tool of claim 1, wherein: one of the first drawer, the second drawer, the third drawer and the fourth drawer is provided with a cylindrical second bulge with an axis arranged along the vertical direction at the inner bottom, and the height of the second bulge is 0.3-1 cm.

4. The hospital inpatient infection detection management tool of claim 3, wherein: and a second partition plate arranged along the vertical direction is fixed at the inner bottom of one of the first drawer, the second drawer, the third drawer and the fourth drawer.

5. The hospital inpatient infection detection management tool of claim 4, wherein: the inner bottom of one of the first drawer, the second drawer, the third drawer and the fourth drawer is fixed with a test tube rack made of a whole foam board, and the test tube rack is provided with a circular test tube hole with an axis arranged along the vertical direction.

6. The hospital inpatient infection detection management tool of claim 5, wherein: the tops of two opposite side walls on the box body are respectively fixed with a strap.

7. The hospital inpatient infection detection management tool of claim 1, wherein: wheels are fixed at the bottom of the box body.

8. The hospital inpatient infection detection management tool of claim 1, wherein: the upper end of the cover body is provided with a handle.

9. The hospital inpatient infection detection management tool of claim 1, wherein: the side wall of the box body is provided with a rotating shaft which is respectively fixed on the parts right above the first drawer, the second drawer, the third drawer and the fourth drawer, the axis of the rotating shaft is vertical to the side wall of the box body where the rotating shaft is located, each rotating shaft is rotatably connected with a limiting block, and the limiting blocks are vertically arranged downwards under the self gravity.

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