CN211876475U

CN211876475U - Positive pressure medicine cold storage and insulation box combining semiconductor and phase change refrigeration

Info

Publication number: CN211876475U
Application number: CN202020368281.7U
Authority: CN
Inventors: 成峰; 王瑜; 吴露露; 许鑫洁; 鲍俊
Original assignee: Nanjing Tech University
Current assignee: Nanjing Tech University
Priority date: 2020-03-20
Filing date: 2020-03-20
Publication date: 2020-11-06
Anticipated expiration: 2030-03-20

Abstract

A positive pressure medicine cold storage and insulation box combining a semiconductor and phase change refrigeration belongs to the field of medicine storage and transportation. Aiming at the problems of unreliable cold source and no positive pressure protection of the existing medical refrigerator, the utility model applies the mutual supplement of the phase-change material and the semiconductor refrigeration as the cold source; and the air filtered is introduced into the box body through a positive pressure air pump to maintain a positive pressure state. The main components comprise a cold storage plate, a temperature sensor, a micro-pressure difference sensor, a refrigeration plate, a cooling fan, a storage battery, a controller and the like. The utility model combines the cold supply mode of phase-change material and semiconductor refrigeration to effectively prolong the cold storage and heat preservation time of the medicine in the box body, thereby prolonging the distribution range of the medicine; and the positive pressure state is maintained in the box body, so that the pollution of the outside air is avoided, and the distribution quality and the distribution efficiency of the medical medicines are improved.

Description

Positive pressure medicine cold storage and insulation box combining semiconductor and phase change refrigeration

Technical Field

The utility model relates to a cold-stored insulation can of malleation medicine that combines semiconductor and phase transition refrigeration belongs to medicine storage and carries the field.

Background

The pharmaceutical industry is the industry related to the national demographics and is one of the most promising industries recognized all over the world at present. Along with the development of economy in China, the quality requirements on the medical products are also improved, and particularly the medical products which need to be refrigerated and stored are stricter. During the storage and transportation process of the medicine, proper environmental temperature needs to be maintained, and the medicine is ensured not to deteriorate and lose the efficacy.

To ensure the quality of the refrigerated medicine, the medicine must be stored in a low temperature environment, usually 2 ℃ to 8 ℃. And all links of the refrigerated medicine in transportation include transportation, storage, transportation loading and unloading and the whole cold chain is needed in the connection process, so that the drug effect of the refrigerated medicine is in a good state. The box on the existing market uses the coolant mostly, for example CN201910525710.5 has proposed a portable heat preservation medicine box, utilizes phase change material to fill the heat preservation, is equipped with the colour development on the lid and marks the subsides, and the colour change through marking the subsides comes the medicine storage temperature in the direct judgement box body whether up to standard, though can learn the temperature in the box, nevertheless be subject to phase change material's single exothermal characteristic, the time relatively fixed when keeping warm, it is not good to the long cold-stored transportation effect of height. Meanwhile, the inside of most of the medical refrigeration and insulation boxes is under normal pressure or negative pressure, such as CN201721835113.9, the negative pressure phase change cold accumulation medical refrigeration and insulation box ensures that the air pressure in the box is lower than the external atmospheric pressure through a physical pressure reduction and chemical adsorption mode, and the negative pressure state ensures that the external atmosphere has a certain pressure covering effect on the insulation box, thereby improving the environmental pollution caused by medicine volatilization; however, the drugs in the medication dispensing boxes should be kept contamination free, and it is considered that the drugs in the boxes are not affected by the outside air, and the negative pressure allows the outside air to enter the boxes more easily, and should not be selected, but should be selected to be in a positive pressure environment.

In order to solve the problems, the utility model designs a medical refrigeration safe box combining the phase-change cold storage material and the semiconductor refrigeration, the phase-change material and the semiconductor refrigeration are mutually supplemented, and the low-temperature duration time in the box is prolonged; the positive pressure state is maintained in the box body, so that the pollution of the outside air is avoided; the storage battery is arranged in the box body, and can provide power for semiconductor refrigeration and positive pressure environment construction. The implementation of this patent will guarantee the cleanliness factor of medical treatment medicine greatly.

Disclosure of Invention

The utility model provides a cold-stored insulation can of malleation medicine that combines semiconductor and phase transition refrigeration mainly comprises outer wall heat preservation 1, cold-storage plate 2, inner wall 3, first temperature sensor 4, second temperature sensor 5, third temperature sensor 6, fourth temperature sensor 7, differential pressure sensor 8, lead cold module 9, refrigeration board 10, semiconductor P end 11, semiconductor N end 12, first metal water conservancy diversion strip 13, second metal water conservancy diversion strip 14, end 15 that generates heat, radiator fan 16, filter equipment 17 admits air, positive pressure gas pump 18, transformer 19, battery 20, controller 21, handle 22, case lid 23, power source 24, box 25, bottom of the box 26, storing bottom 27;

the controller 21 is connected with ten wires and respectively connected with the first temperature sensor 4, the second temperature sensor 5, the third temperature sensor 6, the fourth temperature sensor 7, the micro-pressure difference sensor 8, the storage battery 20, the transformer 19, the first metal flow guide strip 13, the second metal flow guide strip 14 and the cooling fan 16, the storage battery 20 is connected with the air inlet filtering device 17 through the positive pressure air pump 18, the upper sides of the semiconductor P end 11 and the semiconductor N end 12 are connected with the refrigerating plate 10 through the first metal flow guide strip 13, and the refrigerating plate 10 is connected with the cold guide module 9; the lower sides of the semiconductor P end 11 and the semiconductor N end 12 are connected with a heating end 15 through a second metal guide strip 14, the heating end 15 is connected with a radiating fan 16, a power supply interface 24 is connected with a controller 21 through a transformer 19, and the controller 21 is also connected with a micro differential pressure sensor 8;

the air inlet filtering device 17 is installed at the right lower corner of the outer wall heat-insulating layer 1 of the box body 25, the power supply interface 24 is installed right below the outer wall heat-insulating layer 1 of the box body 25, the cold guide module 9 is installed at the center of the storage bottom 27, the refrigeration plate 10 is connected with the cold guide module 9 up and down, namely the refrigeration plate 10 is positioned right below the cold guide module 9, the refrigeration plate 10 is connected with the first metal flow guide strip 13 up and down, the heat radiation fan 16 is installed at the center of the box body bottom 26, the heating end 15 is connected with the heat radiation fan 16 up and down, namely the heating end 15 is positioned right above the box body bottom 26, the heating end 15 is connected with the second metal flow guide strip 14, the semiconductor P end 11 and the semiconductor N end 12 are connected between the first metal flow guide strip 13 and the second metal flow guide strip 14, the semiconductor P end 11 and the semiconductor N end 12 are not contacted with each other, the controller, the transformer 19 is arranged in the middle of the controller 21 and the power interface 24, the storage battery 20 is arranged at the horizontal position of the right view of the controller 21, the positive pressure air pump 18 is arranged at the upper right corner of the storage bottom 27, the cooling fan 16 is arranged in the hollowed space inside the box bottom 26 and is positioned below the heating end 15, the cold guide module 9 and the positive pressure air pump 18 are arranged in the reserved space inside the storage bottom 27, the positive pressure air pump 18 is arranged at the upper right corner of the cold guide module 9, and the cold accumulation plate 2 is arranged between the outer wall heat preservation layer 1 and the inner wall 3 of the box 25; the box body bottom 26 is arranged right below the storage bottom 27, the box body 25 is arranged right above the storage bottom 27, the height between the box body bottom 26 and the storage bottom 27 is limited by being capable of accommodating the lower refrigerating plate 10, the semiconductor P end 11, the semiconductor N end 12, the first metal flow guide strip 13, the second metal flow guide strip 14 and the heating end 15, and the box cover 23 is arranged at the top of the box body 25;

the bottom of the box body 25 is provided with a first temperature sensor 4, a second temperature sensor 5, a third temperature sensor 6, a fourth temperature sensor 7 and a micro differential pressure sensor 8, the first temperature sensor 4, the second temperature sensor 5, the third temperature sensor 6 and the fourth temperature sensor 7 are respectively arranged at four corners inside the box body 25, the micro differential pressure sensor 8 is arranged at the diagonal position of the positive pressure air pump 18, and probes of the first temperature sensor 4, the second temperature sensor 5, the third temperature sensor 6, the fourth temperature sensor 7 and the micro differential pressure sensor 8 are all 1-2 cm above the storage bottom 27;

the cold storage plate 2 between the outer wall heat preservation layer 1 and the inner wall 3 is changed into a solid after being charged with cold, so as to provide cold energy for the box body 25, and the phase change material maintains the temperature in the box body between 2 ℃ and 8 ℃;

when the temperature in the box rises, the first temperature sensor 4, the second temperature sensor 5, the third temperature sensor 6 and the fourth temperature sensor 7 collect the temperature data in the box body 25 and transmit the temperature data to the controller 21, when the temperature is higher than a certain set value, the controller 21 is started, the storage battery 20 provides direct current, the semiconductor P end 11 and the semiconductor N end 12 are connected through the first metal diversion strip 13 and the second metal diversion strip 14, cold energy is generated at the cold plate 10, and the cold energy is emitted into the box body 25 through the cold guide module 9; meanwhile, the heat generated by the heating end 15 of the semiconductor refrigeration is transferred to the external environment by the heat radiation fan 16 through a forced convection mode;

the controller 21 is also connected with a micro differential pressure sensor 8, when the micro differential pressure sensor 8 detects that the pressure in the box is lower than a certain set value, the storage battery 20 starts to supply power, the electric quantity is transmitted to the positive pressure air pump 18 through the controller 21, the controller 21 starts the positive pressure air pump 18, external air is introduced through the air inlet filtering device 17, the positive pressure in the box body 25 is ensured, and the positive pressure air pump 18 maintains the positive pressure in the box body 25;

the phase change material in the cold accumulation plate 2 is inorganic salt solution, the filtering material in the intake air filtering device 17 is nano activated carbon and anhydrous calcium chloride, the outer wall heat preservation layer 1 is made of vacuum heat insulation plate high heat resistance material, the inner wall 3 is made of aluminum alloy, and the box body 25 and the box cover 23 are made of polypropylene;

the positive pressure air pump 18 maintains the positive pressure in the box body 25 to be 12.5 Pa;

the filter material in the air inlet filter device 17 is nano active carbon and anhydrous calcium chloride;

the power interface 24 is externally connected with an alternating current power supply, and stores electric quantity in the storage battery 20, the storage battery 20 supplies electric quantity for the work of the first temperature sensor 4, the second temperature sensor 5, the third temperature sensor 6, the fourth temperature sensor 7 and the micro-differential pressure sensor 8 through the controller 21, and also supplies direct current for the work of the controller 21, the semiconductor P end 11, the semiconductor N end 12, the first metal flow guide strip 13, the second metal flow guide strip 14, the heating end 15 and the cooling fan 16;

the first temperature sensor 4, the second temperature sensor 5, the third temperature sensor 6 and the fourth temperature sensor 7 adopt intelligent sensor chips of digital analog mixed signals with high integration level, and the micro differential pressure sensor 8 adopts a high-performance silicon piezoresistive differential pressure chip;

the phase change material in the cold storage plate 2 is 10% Na₂CO₃An inorganic salt solution.

Drawings

Fig. 1 is a perspective view of the present invention.

Reference designations in FIG. 1: 1. the air conditioner comprises an outer wall heat preservation layer, 2 parts of cold accumulation plates, 3 parts of inner walls, 4 parts of first temperature sensors, 5 parts of second temperature sensors, 6 parts of third temperature sensors, 7 parts of fourth temperature sensors, 8 parts of micro-differential pressure sensors, 9 parts of cold conduction modules, 10 parts of refrigeration plates, 11 parts of semiconductor P ends, 12 parts of semiconductor N ends, 13 parts of first metal guide strips, 14 parts of second metal guide strips, 15 parts of heating ends, 16 parts of cooling fans, 17 parts of air inlet filtering devices, 18 parts of positive pressure air pumps, 19 parts of transformers, 20 parts of storage batteries, 21 parts of controllers, 22 parts of handles, 23 parts of box covers, 24 parts of power interfaces, 25 parts of box bodies, 26 parts of box bodies and 27 parts of storage bottoms.

Fig. 2 is a front view of the present invention.

Reference number designation in figure 2: 1. the refrigerator comprises an outer wall heat preservation layer, an inner wall, 4, a first temperature sensor, 5, a second temperature sensor, 8, a micro-differential pressure temperature sensor, 9, a cold conduction module, 10 a refrigeration plate, 11, a semiconductor P end, 12, a semiconductor N end, 13, a first metal diversion strip, 14, a second metal diversion strip, 15, a heating end, 16, a cooling fan, 18, a positive pressure air pump, 19, a transformer, 20, a storage battery, 21, a controller, 22, a handle, 26, a box body bottom and 27, and a storage bottom.

Fig. 3 is a top view of the present invention.

Reference number designations in FIG. 3: 4. the device comprises a first temperature sensor, 5, a second temperature sensor, 6, a third temperature sensor, 7, a fourth temperature sensor, 8, a micro-pressure difference sensor, 9, a cold guide module, 18, a positive pressure air pump, 19, a transformer, 20, a storage battery, 21, a controller and 27, and a storage bottom.

Fig. 4 is a right side view of the present invention.

The reference numbers in FIG. 4 refer to: 5. the device comprises a second temperature sensor, 6, a third temperature sensor, 8, a micro-pressure difference sensor, 9, a cold guide module, 10, a refrigeration plate, 12, a semiconductor N end, 13, a first metal diversion strip, 14, a second metal diversion strip, 15, a heating end, 17, an air inlet filtering device, 18, a positive pressure air pump, 20, a storage battery, 21, a controller, 22, a handle, 24, a power interface, 26, the bottom of a box body and 27, and a storage bottom.

Detailed Description

As shown in fig. 1, a positive pressure medical refrigeration and insulation box combining semiconductor and phase change refrigeration mainly comprises an outer wall insulation layer 1, a cold storage plate 2, an inner wall 3, a first temperature sensor 4, a second temperature sensor 5, a third temperature sensor 6, a fourth temperature sensor 7, a micro-pressure difference sensor 8, a cold guide module 9, a refrigeration plate 10, a semiconductor P end 11, a semiconductor N end 12, a first metal flow guide strip 13, a second metal flow guide strip 14, a heating end 15, a cooling fan 16, an air inlet filtering device 17, a positive pressure air pump 18, a transformer 19, a storage battery 20, a controller 21, a handle 22, a box cover 23, a power supply interface 24, a box body 25, a box body bottom 26 and a storage bottom 27.

The cold storage and insulation box uses phase change material cold accumulation as a cold source in the box body, and uses semiconductor refrigeration as an auxiliary cold source. Before use, the cold storage plate 2 between the outer wall heat preservation layer 1 and the inner wall 3 is filled with solid phase change materials, electric quantity is stored in the storage battery 20 through the power interface 24, the phase change materials provide cold for the box body 25, and the temperature in the box body is maintained between 2 ℃ and 8 ℃. When the temperature in the box rises, the first temperature sensor 4, the second temperature sensor 5, the third temperature sensor 6 and the fourth temperature sensor 7 collect the temperature data in the box body 25 of the box body and transmit the temperature data to the controller 21, when the temperature is higher than a certain set value, the semiconductor refrigeration is started, the storage battery 20 starts to supply power, the electric quantity is transmitted to the P end 11 of the semiconductor and the N end 12 of the semiconductor through the first metal diversion strip 13 and the second metal diversion strip 14, the cold quantity is generated at the cold producing plate 10, and the cold quantity is emitted into the box body 25 through the cold conducting module 9; at the same time, the heat generated by the heat generating end 15 of the semiconductor refrigeration is transferred to the outside air by the heat dissipation fan 16 through forced convection.

The micro differential pressure sensor 8 is connected to the controller 21, when the pressure in the box is lower than a certain set value, the storage battery 20 starts to supply power, the electric quantity is transmitted to the positive pressure air pump 18 through the controller 21, the positive pressure in the box is ensured by the positive pressure air pump 18, the fresh air is the outside air passing through the air inlet filtering device 17, the nano activated carbon and the anhydrous calcium chloride are filled in the air inlet filtering device 17, and the cleanliness of the entering air is ensured.

The utility model combines the characteristics of semiconductor refrigeration and phase change cold accumulation, effectively prolongs the refrigeration and heat preservation time of the environment in the box body, thereby prolonging the distribution range of the medicine and providing guarantee for more patients; in addition, the positive pressure state is maintained in the box body, so that the pollution of the outside air is avoided, and the medicine is protected; the storage battery is arranged in the box body, and can provide power for semiconductor refrigeration and positive pressure environment construction. The implementation of this patent will improve the distribution quality and the distribution efficiency of medical drug.

Claims

1. The utility model provides a cold-stored insulation can of malleation medicine that combines semiconductor and phase transition refrigeration which characterized in that:

the device is composed of an outer wall heat-insulating layer (1), a cold accumulation plate (2), an inner wall (3), a first temperature sensor (4), a second temperature sensor (5), a third temperature sensor (6), a fourth temperature sensor (7), a micro-differential pressure sensor (8), a cold conduction module (9), a refrigeration plate (10), a semiconductor P end (11), a semiconductor N end (12), a first metal flow guide strip (13), a second metal flow guide strip (14), a heating end (15), a cooling fan (16), an air inlet filtering device (17), a positive pressure air pump (18), a transformer (19), a storage battery (20), a controller (21), a handle (22), a box cover (23), a power interface (24), a box body (25), a box body bottom (26) and a storage bottom (27);

the controller (21) is connected with ten wires and is respectively connected with a first temperature sensor (4), a second temperature sensor (5), a third temperature sensor (6), a fourth temperature sensor (7), a micro-differential pressure sensor (8), a storage battery (20), a transformer (19), a first metal flow guide strip (13), a second metal flow guide strip (14) and a cooling fan (16), the storage battery (20) is connected with an air inlet filtering device (17) through a positive pressure air pump (18), the upper sides of a semiconductor P end (11) and a semiconductor N end (12) are connected with a refrigerating plate (10) through the first metal flow guide strip (13), and the refrigerating plate (10) is connected with a cold guide module (9); the lower sides of a semiconductor P end (11) and a semiconductor N end (12) are connected with a heating end (15) through a second metal guide strip (14), the heating end (15) is connected with a cooling fan (16), a power supply interface (24) is connected with a controller (21) through a transformer (19), and the controller (21) is also connected with a micro-pressure difference sensor (8);

the air inlet filtering device (17) is installed at the right lower corner of an outer wall heat-insulating layer (1) of the box body (25), the power supply interface (24) is installed under the outer wall heat-insulating layer (1) of the box body (25), the cold guide module (9) is installed in the middle of a storage bottom (27), the refrigerating plate (10) is connected with the cold guide module (9) up and down, namely the refrigerating plate (10) is positioned under the cold guide module (9), the refrigerating plate (10) is connected with the first metal guide strip (13) up and down, the radiating fan (16) is installed in the middle of the bottom (26) of the box body, the heating end (15) is connected with the radiating fan (16) up and down, namely the heating end (15) is positioned above the bottom (26) of the box body, the heating end (15) is connected with the second metal guide strip (14), the semiconductor P end (11) is connected with the semiconductor N end (12) between the first metal guide strip (13) and the second metal guide strip (14), the semiconductor P end (11) and the semiconductor N end (12) are not in contact with each other, the controller (21) is installed on the right side of the semiconductor N end (12), the transformer (19) is installed in the middle of the controller (21) and the power interface (24), the storage battery (20) is installed at the horizontal position of the right view of the controller (21), the positive pressure air pump (18) is installed at the upper right corner of the storage bottom (27), the heat dissipation fan (16) is installed in the space dug out of the box bottom (26) and located below the heat generation end (15), the cold guide module (9) and the positive pressure air pump (18) are installed in the space reserved in the storage bottom (27), the positive pressure air pump (18) is installed at the upper right corner of the cold guide module (9), and the cold storage plate (2) is installed between the outer wall heat insulation layer (1) and the inner wall (3) of the box body (; the refrigerator is characterized in that the bottom (26) of the refrigerator body is arranged right below the bottom (27) of the storage box, the refrigerator body (25) is arranged right above the bottom (27) of the storage box, the height between the bottom (26) of the refrigerator body and the bottom (27) of the storage box is limited by being capable of accommodating the lower refrigerating plate (10), the semiconductor P end (11), the semiconductor N end (12), the first metal flow guide strip (13), the second metal flow guide strip (14) and the heating end (15), and the refrigerator cover (23) is arranged at the top of the refrigerator body (25);

the bottom of box (25) is equipped with first temperature sensor (4), second temperature sensor (5), third temperature sensor (6), fourth temperature sensor (7), differential pressure sensor (8), first temperature sensor (4), second temperature sensor (5), third temperature sensor (6), four corners at box (25) inside are installed respectively in fourth temperature sensor (7), differential pressure sensor (8) are installed in the diagonal position of positive pressure air pump (18), first temperature sensor (4), second temperature sensor (5), third temperature sensor (6), the probe of fourth temperature sensor (7) and differential pressure sensor (8) all is 1 to 2cm on storing bottom (27).

2. The positive pressure medicine refrigeration and heat preservation box combining the semiconductor and the phase-change refrigeration as claimed in claim 1, characterized in that:

the cold storage plate (2) between the outer wall heat preservation layer (1) and the inner wall (3) is changed into a solid after being charged with cold to provide cold energy for the box body (25), and the phase change material maintains the temperature in the box body between 2 ℃ and 8 ℃;

when the temperature in the box rises, the first temperature sensor (4), the second temperature sensor (5), the third temperature sensor (6) and the fourth temperature sensor (7) collect the temperature data in the box body (25) and transmit the temperature data to the controller (21), when the temperature is higher than a certain set value, the controller (21) is started, the storage battery (20) provides direct current, the semiconductor P end (11) and the semiconductor N end (12) are connected through the first metal diversion strip (13) and the second metal diversion strip (14), cold energy is generated at the refrigerating plate (10), and the cold energy is emitted into the box body (25) through the cold conducting module (9); meanwhile, the heat generated by the heating end (15) of the semiconductor refrigeration is transferred to the external environment by the heat radiation fan (16) in a forced convection mode;

the controller (21) is also connected with a micro-pressure difference sensor (8), when the micro-pressure difference sensor (8) detects that the pressure in the box is lower than a certain set value, the storage battery (20) starts to supply power, the electric quantity is transmitted to the positive pressure air pump (18) through the controller (21), the controller (21) starts the positive pressure air pump (18), the external air is introduced through the air inlet filtering device (17), and the positive pressure of the box body (25) is ensured.

3. The positive pressure medicine refrigeration and heat preservation box combining the semiconductor and the phase-change refrigeration as claimed in claim 1, characterized in that: the phase-change material in the cold storage plate (2) is inorganic salt solution, the filtering material in the air inlet filtering device (17) is nano activated carbon and anhydrous calcium chloride, the outer wall heat-insulating layer (1) is made of vacuum heat-insulating plate high-heat-resistance material, the inner wall (3) is made of aluminum alloy, and the box body (25) and the box cover (23) are made of polypropylene.

4. The positive pressure medicine refrigeration and heat preservation box combining the semiconductor and the phase-change refrigeration as claimed in claim 1, characterized in that: the positive pressure air pump (18) maintains the positive pressure in the box body (25) to be 12.5 Pa.

5. The positive pressure medicine refrigeration and heat preservation box combining the semiconductor and the phase-change refrigeration as claimed in claim 1, characterized in that: the filter material in the air inlet filter device (17) is nano active carbon and anhydrous calcium chloride.

6. The positive pressure medicine refrigeration and heat preservation box combining the semiconductor and the phase-change refrigeration as claimed in claim 1, characterized in that: power source (24) external AC power supply, store the electric quantity in battery (20), battery (20) provide the electric quantity for first temperature sensor (4), second temperature sensor (5), third temperature sensor (6), fourth temperature sensor (7) and minute pressure difference sensor (8) work through controller (21), also provide the direct current for controller (21) and semiconductor P end (11), semiconductor N end (12), first metal water conservancy diversion strip (13), second metal water conservancy diversion strip (14), end (15) generate heat, radiator fan (16) during operation.

7. The positive pressure medicine refrigeration and heat preservation box combining the semiconductor and the phase-change refrigeration as claimed in claim 1, characterized in that: the first temperature sensor (4), the second temperature sensor (5), the third temperature sensor (6) and the fourth temperature sensor (7) adopt intelligent sensor chips with high-integration digital-analog mixed signals, and the micro differential pressure sensor (8) adopts a high-performance silicon piezoresistive differential pressure chip.

8. The positive pressure medicine refrigeration and heat preservation box combining the semiconductor and the phase-change refrigeration as claimed in claim 1, characterized in that: the phase change material in the cold storage plate (2) is 10% Na₂CO₃An inorganic salt solution.