CN114044247B - Biological medicine storage equipment - Google Patents

Abstract

The invention discloses biological medicine storage equipment, which belongs to the technical field of medical equipment, and comprises a main shell, a plurality of storage cavities and a refrigerator, wherein a partition plate assembly comprising a main partition plate and a sealing plate is arranged between the storage cavities, a plurality of plugging holes are arranged on the sealing plate, the plugging holes are correspondingly arranged with slots on the main partition plate and are used for sliding and plugging the main partition plate, a storage carrier is slidably arranged between the partition plate assemblies and is in linkage arrangement with the partition plate assembly and is used for driving the sealing plate to plug the main partition plate, a bottle rack assembly comprising a plurality of bottle racks is assembled in the storage carrier and is in linkage arrangement with the storage carrier and is used for driving a medicine bottle to tilt, so that labels on the surface of the medicine bottle are convenient to view.

Description

Biological medicine storage equipment

Technical Field

The invention belongs to the technical field of medical equipment, and particularly relates to biological medicine storage equipment.

Background

It is common for medicines in life to be purchased and taken mainly under the guidance of doctors. The medicines can purposefully regulate physiological functions of people, and are provided with indications or functional indications, usage and dosage of substances including traditional Chinese medicines, chemical medicines, biological products and the like, and can be classified into various kinds according to the properties thereof, such as traditional Chinese medicines, chinese patent medicines, antibiotics, serum, vaccines and blood products, wherein the included serum, vaccines and blood products are biological medicines.

The biological medicine is one kind of medicine prepared with organism, biological tissue, organ and other components and through comprehensive application of biological, biochemical, microbiological, immunological, physicochemical and pharmaceutical principles and methods, including protein, enzyme, nucleic acid, hormone, antibody, cell factor, etc.

Compared with the conventional medicine, the biological medicine has higher requirement on the preservation environment, is usually preserved at a low temperature below 5 ℃, the existing preservation device of the biological medicine bottle comprises a refrigerator or a storage box, and the cold air in the biological medicine bottle can be continuously lost by opening and closing the preservation device in the process of taking the medicine bottle, so that the power consumption of equipment is increased, and the medicine bottle is not convenient to take.

Disclosure of Invention

In view of the shortcomings of the prior art, an object of an embodiment of the present invention is to provide a biopharmaceutical storage device, so as to solve the problems in the prior art.

In order to achieve the above purpose, the present invention provides the following technical solutions:

a biopharmaceutical storage device comprising a housing member comprising a main housing, a number of preserving cavities and a refrigerator, the biopharmaceutical storage device further comprising:

the baffle assembly comprises a main baffle and a sealing plate, wherein the main baffle is fixedly assembled between a plurality of storage cavities, a plurality of slotted holes are arranged on the surface of the main baffle, the sealing plate is slidably installed on one side of the main baffle, a plurality of plugging holes are arranged on the surface of the sealing plate, and the plugging holes are correspondingly arranged with the slotted holes and are used for controlling the opening and closing of one side of the plugging holes when the sealing plate slides relative to the main baffle;

the storage carrier is arranged in the biological medicine storage equipment in a linkage way and is used for driving the sealing plate to movably seal the main partition plate when the storage carrier slides relative to the partition plate assembly so that the preservation cavity at the side is isolated from other preservation cavities; and

the bottle rack assembly comprises a plurality of bottle racks for containing biological medicine bottles, the bottle racks are rotationally assembled in the storage carrier and are in linkage with the storage carrier, so that when the storage carrier slides to the outer side of the main shell, the bottle racks drive the medicine bottles to synchronously tilt, and labels on the surfaces of the biological medicine bottles are convenient to view.

As a further aspect of the present invention, the housing member further includes:

the guide groove is arranged on the inner wall of the main shell and is in sliding fit with the storage carrier; and

and the control board is electrically connected with the refrigerator and used for adjusting the temperature inside the main shell.

As a further aspect of the present invention, the partition assembly further includes an abutment block disposed on a surface of the main partition and disposed near one side of the exterior of the storage chamber, for movably abutting the bottle holder assembly.

As a further aspect of the present invention, the separator assembly further includes:

the limiting groove is arranged on the surface of the main partition board and is arranged close to one side outside the preservation cavity; and

the driving block is fixedly arranged on the surface of the sealing plate and matched with the limiting groove, and one end of the driving block is slidably inserted into the limiting groove.

As a further aspect of the present invention, the storage carrier includes:

the carrier body is assembled in the guide groove in a sliding way, and a plurality of air guide holes are distributed at the bottom of the carrier body;

the magnetic attraction piece is assembled on one side of the carrier main body and is used for being magnetically attached to the main shell and the main partition plate so as to enable the carrier main body to be in sealing connection with the main shell and the preservation cavity;

the trigger piece is fixedly arranged on the carrier main body and is arranged close to one side of the driving block and is used for movably abutting against the driving block; and

the side connecting pieces are arranged on two sides of the carrier main body and movably abutted with the driving blocks.

As a further aspect of the present invention, the bottle holder assembly further includes:

the driving rod is movably connected with the bottle racks through slot interfaces and is used for driving the bottle racks to synchronously rotate; and

the driving piece is arranged at the tail end of the driving rod and is used for movably abutting against the abutting block.

As a further aspect of the present invention, the rotation direction of the bottle holder is set toward the inside of the preservation chamber.

In summary, compared with the prior art, the embodiment of the invention has the following beneficial effects:

according to the invention, the storage carrier arranged between the baffle plate assemblies in a sliding manner can be used for opening and closing the storage carrier to take the medicine bottle, and meanwhile, the main baffle plate is movably opened and closed through the sealing plate, so that the loss of electric quantity of equipment is reduced, and meanwhile, the medicine bottle can be driven to tilt after the storage carrier is opened, so that the medicine bottle can be conveniently and rapidly checked and taken.

In order to more clearly illustrate the structural features and efficacy of the present invention, the present invention will be described in detail below with reference to the accompanying drawings and examples.

Drawings

Fig. 1 is a schematic structural view of a biopharmaceutical storage device according to an embodiment of the present invention.

Fig. 2 is a schematic structural view of a graphic symbol a in a biopharmaceutical storage device according to an embodiment of the present invention.

Fig. 3 is a schematic side view of a biopharmaceutical storage device according to an embodiment of the present invention.

Fig. 4 is a schematic structural view of a graphic symbol B in a biopharmaceutical storage device according to an embodiment of the present invention.

Fig. 5 is a schematic perspective view of a septum assembly of a biopharmaceutical storage device according to one embodiment of the present invention.

Reference numerals: 1-housing component, 101-main housing, 102-storage chamber, 103-guide slot, 104-refrigerator, 105-control panel, 2-partition assembly, 201-main partition, 202-slot, 203-slide slot, 204-seal plate, 205-abutment block, 206-limit slot, 207-drive block, 208-block hole, 209-elastic piece, 3-storage carrier, 301-carrier body, 302-air vent, 303-magnetic piece, 304-trigger piece, 4-bottle rack assembly, 401-bottle rack, 402-drive rod, 403-drive piece, 404-slot interface.

Detailed Description

Specific implementations of the invention are described in detail below in connection with specific embodiments.

Referring to fig. 1-5, a biopharmaceutical storage apparatus according to an embodiment of the present invention includes a housing member 1, the housing member 1 including a main housing 101, a plurality of storage cavities 102 and a refrigerator 104, the biopharmaceutical storage apparatus further comprising: the partition board assembly 2, wherein the partition board assembly 2 comprises a main partition board 201 and a sealing board 204, the main partition board 201 is fixedly assembled between a plurality of storage cavities 102, a plurality of slotted holes 202 are distributed on the surface of the main partition board, the sealing board 204 is slidably installed on one side of the main partition board 201, a plurality of plugging holes 208 are distributed on the surface of the sealing board 204, and the plugging holes 208 are correspondingly arranged with the slotted holes 202 and are used for controlling the opening and closing of one side of the plugging holes 208 when the sealing board 204 slides relative to the main partition board 201; the storage carrier 3, the biopharmaceutical storage device includes a plurality of storage carriers 3, the storage carriers 3 are slidably mounted between the partition board assemblies 2, and the storage carriers 3 are arranged in linkage with the partition board assemblies 2, so that when the storage carriers 3 slide relative to the partition board assemblies 2, the driving sealing board 204 movably seals the main partition board 201, and the preservation cavity 102 at the side is isolated from the rest preservation cavities 102; and the bottle rack assembly 4, the bottle rack assembly 4 includes a plurality of bottle racks 401 for hold the biological medicine bottle, a plurality of bottle racks 401 rotate and assemble in storing carrier 3, and with storing carrier 3 linkage setting, so that when storing carrier 3 slides to the main casing 101 outside, a plurality of bottle racks 401 drive the medicine bottle and incline in step, make the label on biological medicine bottle surface be convenient for look over.

In practical application, when the device is required to store the biological medicine bottles, the main housing 101 comprises a plurality of storage cavities 102, the storage cavities 102 are separated by the partition plate component 2, the storage carrier 3 is slidably inserted between the partition plate components 2, in the process of storing the biological medicine bottles, as the storage standard of the biological medicine to the temperature is higher, the standard condition is required to be kept below 5 ℃, when the medicine bottles are taken in the conventional medicine storage device, the cold air flow in the device can be quickly exchanged with the external hot air flow in the process of opening and closing the device, so that the temperature in the device can generate a variation difference value, on one hand, the cold air in the device can be lost in the repeated opening and closing process, the power consumption is increased, and on the other hand, part of medicine can damage the potency at the variation temperature, in the storage carrier 3 in this embodiment, during the opening process, since one side of the storage carrier 3 is in linkage with the partition board assembly 2, the sealing board 204 in the main partition board 201 slides relative to the main partition board 201, and a plurality of plugging holes 208 corresponding to the main partition board 201 on the original sealing board 204 slide and then are staggered with the slot holes 202, so that a passage formed between the main partition board 201 and the sealing board 204 is closed, and the air in the rest storage cavities 102 is not in heat exchange with the outside, thereby not only reducing the power consumption and improving the environmental protection effect, but also the bottle rack assembly 4 which is in linkage with the storage carrier 3 moves synchronously while opening the storage carrier 3, so that the medicine bottle placed in the bottle rack 401 can be driven to tilt, the label of the medicine bottle rotates towards the outer side, and the required medicine bottle is convenient to view and take, and the taking and placing efficiency is improved.

In one case of this embodiment, the main housing 101 is integrally made of a heat insulation material, so as to improve the refrigerating effect of the device in the heat insulation environment, which is not described in detail herein.

Referring to fig. 1, in a preferred embodiment of the invention, the housing member 1 further comprises: a guide groove 103 arranged on the inner wall of the main housing 101 and in sliding fit with the storage carrier 3; and a control board 105 electrically connected to the refrigerator 104 for adjusting the temperature inside the main casing 101.

In practical application, the storage carrier 3 is slidably assembled on the guide groove 103 and is not in sliding contact with the partition board assembly 2, so that the storage carrier 3 is ensured not to interfere with the flow of the cold air in the partition board assembly 2 in the moving process.

In one case of this embodiment, the refrigerator 104 may be a vapor compression refrigerator or a gas compression refrigerator, which is more suitable for cooling the vial storage device in consideration of the actual working environment, but is not specifically limited herein as long as it can stably cool and preserve the biopharmaceutical.

Referring to fig. 5, in a preferred embodiment of the invention, the partition assembly 2 further includes an abutment block 205, where the abutment block 205 is disposed on the surface of the main partition 201 and is disposed near the outer side of the storage chamber 102, for movably abutting the bottle rack assembly 4.

In practical application, the abutting block 205 is fixedly arranged on the main partition 201, and the main partition 201 is fixedly arranged in the main housing 101, and when the storage carrier 3 drives the bottle rack assembly 4 to slide to one side of the abutting block 205, the abutting block 205 is movably abutted to the bottle rack assembly 4, and drives the bottle racks 401 in the storage carrier 3 to tilt synchronously.

Referring to fig. 5, in a preferred embodiment of the present embodiment, the partition board assembly 2 further includes: the limiting groove 206 is arranged on the surface of the main partition 201 and is arranged near one side outside the preservation cavity 102; and a driving block 207 fixedly arranged on the surface of the sealing plate 204 and matched with the limit groove 206, wherein one end of the driving block is slidably inserted into the limit groove 206.

In practical application, the driving block 207 is slidably inserted into the limiting groove 206, and the upper and lower ends of the driving block 207 are both linked with the storage carrier 3, and the sealing plate 204 slides along the sliding groove 203 under the driving of the storage carrier 3, so that the plurality of plugging holes 208 correspondingly communicated with the slot 202 are staggered with the slot 202 after sliding, so that the slot 202 and the plugging holes 208 are staggered and separated, and the storage cavities 102 of the upper and lower layers of the partition plate assembly 2 are sealed and isolated.

In one case of this embodiment, the sealing plate 204 is elastically assembled in the chute 203 by the elastic member 209, and after the storage carrier 3 slides reversely into the main housing 101, the sealing plate 204 is quickly restored under the elastic force of the elastic member 209, and the main partition 201 is driven again to communicate with the sealing plate 204.

Referring to fig. 2 and 4, in a preferred embodiment of the invention, the storage carrier 3 comprises: the carrier body 301 is slidably assembled in the guide groove 103, and a plurality of air guide holes 302 are arranged at the bottom of the carrier body 301; a magnetic attraction member 303, which is assembled on one side of the carrier main body 301 and is used for magnetically attaching the main casing 101 and the main partition 201, so that the carrier main body 301 is in sealing connection with the main casing 101 and the preservation chamber 102; the trigger piece 304 is fixedly arranged on the carrier main body 301 and is arranged near one side of the driving block 207 for movably abutting against the driving block 207; and side pieces 305 disposed on both sides of the carrier body 301 and movably abutting against the driving block 207.

In practical application, when the carrier body 301 slides along the guide groove 103, the trigger piece 304 on the top side of the carrier body 301 is movably abutted with the driving block 207 on the top side of the carrier body 301, and the sealing plate 204 slides relative to the main partition 201 by pushing the driving block 207 to move, so that the main partition 201 is movably blocked, and meanwhile, the side piece 305 on the bottom side of the carrier body 301 is movably abutted with the driving block 207 on the bottom side of the carrier body 301, so that the main partition 201 on the bottom side of the carrier body 301 is synchronously movably blocked, so that the carrier body 301 in the side storage cavity 102 is isolated from the rest storage cavities 102 after sliding outwards.

In one case of this embodiment, the magnetic attraction member 303 preferably adopts a magnetic adhesive tape wrapped by polyvinyl chloride, which has an excellent sealing effect and also has a good heat preservation effect, so that heat exchange between the inside and the outside of the device is reduced.

In one case of the present embodiment, the side member 305 is provided near the inside of the preservation chamber 102.

Referring to fig. 4, in a preferred embodiment of the invention, the bottle holder assembly 4 further comprises: the driving rod 402 is movably connected with the bottle racks 401 through the slot interfaces 404 and is used for driving the bottle racks 401 to synchronously rotate; and a driving element 403, disposed at the end of the driving rod 402, for movably abutting against the abutment block 205; the rotation direction of the bottle holder 401 is set toward the inside of the preservation chamber 102.

In practical application, when the driving piece 403 is movably abutted with the abutment block 205, the driving rod 402 slidably mounted on one side of the carrier main body 301 synchronously drives the bottle holders 401 to tilt through the slot interface 404, so that the label pages of the medicine bottles rotate outwards, and therefore, compared with the medicine bottles under the conventional placing condition, the medicine bottle information can be conveniently and quickly checked, and the medicine bottle information can be manually taken due to shielding among the bottle bodies.

In the above embodiment of the invention, the storage carrier 3 arranged between the baffle assemblies 2 in a sliding manner is provided, so that the main baffle 201 can be movably opened and closed through the sealing plate 204 while the storage carrier 3 is opened and closed to take the medicine bottle, the electric quantity loss of the device is reduced, and meanwhile, the medicine bottle can be driven to tilt after the storage carrier is opened, so that the medicine bottle can be conveniently and rapidly checked and taken.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the invention.

Claims (7)

1. A biopharmaceutical storage device comprising a housing member comprising a main housing, a number of preserving cavities and a refrigerator, characterized in that the biopharmaceutical storage device further comprises:

the baffle assembly comprises a main baffle and a sealing plate, wherein the main baffle is fixedly assembled between a plurality of storage cavities, a plurality of slotted holes are arranged on the surface of the main baffle, the sealing plate is slidably installed on one side of the main baffle, a plurality of plugging holes are arranged on the surface of the sealing plate, and the plugging holes are correspondingly arranged with the slotted holes and are used for controlling the opening and closing of one side of the plugging holes when the sealing plate slides relative to the main baffle;

the storage carrier is arranged in the biological medicine storage equipment in a linkage way and is used for driving the sealing plate to movably seal the main partition plate when the storage carrier slides relative to the partition plate assembly so that the preservation cavity at the side is isolated from other preservation cavities; and

the bottle rack assembly comprises a plurality of bottle racks for containing biological medicine bottles, the bottle racks are rotationally assembled in the storage carrier and are in linkage with the storage carrier, so that when the storage carrier slides to the outer side of the main shell, the bottle racks drive the medicine bottles to synchronously tilt, and labels on the surfaces of the biological medicine bottles are convenient to view.

2. The biopharmaceutical storage device of claim 1, wherein the housing member further comprises:

the guide groove is arranged on the inner wall of the main shell and is in sliding fit with the storage carrier; and

and the control board is electrically connected with the refrigerator and used for adjusting the temperature inside the main shell.

3. The biopharmaceutical storage apparatus of claim 1, wherein the spacer assembly further comprises an abutment disposed on a surface of the main spacer and disposed adjacent an exterior side of the storage cavity for movably abutting the bottle holder assembly.

4. The biopharmaceutical storage apparatus of claim 1, wherein the diaphragm assembly further comprises:

the limiting groove is arranged on the surface of the main partition board and is arranged close to one side outside the preservation cavity; and

the driving block is fixedly arranged on the surface of the sealing plate and matched with the limiting groove, and one end of the driving block is slidably inserted into the limiting groove.

5. A biopharmaceutical storage device according to claim 2, wherein the storage carrier comprises:

the carrier body is assembled in the guide groove in a sliding way, and a plurality of air guide holes are distributed at the bottom of the carrier body;

the magnetic attraction piece is assembled on one side of the carrier main body and is used for magnetically attaching the carrier main body and the main partition plate so as to enable the carrier main body to be in sealing connection with the main shell and the preservation cavity;

the trigger piece is fixedly arranged on the carrier main body and is arranged close to one side of the driving block and is used for movably abutting against the driving block; and

the side connecting pieces are arranged on two sides of the carrier main body and movably abutted with the driving blocks.

6. A biopharmaceutical storage device according to claim 3, wherein the bottle holder assembly further comprises:

the driving rod is movably connected with the bottle racks through slot interfaces and is used for driving the bottle racks to synchronously rotate; and

the driving piece is arranged at the tail end of the driving rod and is used for movably abutting against the abutting block.

7. The biopharmaceutical storage device of claim 6, wherein the rotational direction of the frame is oriented towards the inside of the preserving cavity.