CN214630987U - Deoxidization locker with electrolyte complementary system - Google Patents

Abstract

A deoxidizing storage cabinet with an electrolyte supplementing system comprises a cabinet body with a storage space, an electronic sieve oxygen generation module, a liquid storage tank and a water storage tank; the electronic sieve oxygen generation module is provided with an air inlet end, an oxygen exhaust end and a liquid inlet end; a liquid storage cavity for storing electrolyte is arranged in the liquid storage tank, a liquid outlet end and a water inlet end which are communicated with the liquid storage cavity are arranged on the liquid storage tank, and the liquid outlet end is communicated with a liquid inlet end of the electronic sieve oxygen production module through a water pipeline; the water storage tank is provided with a water replenishing port, an oxygen inlet and a water outlet end, the water replenishing port is communicated with an inner cavity of the water storage tank, the oxygen inlet is communicated with an oxygen exhaust end of the electronic sieve oxygen production module through an air pipeline, the oxygen inlet is arranged below the liquid level of the water storage tank, and the water outlet end is communicated with a water inlet end of the liquid storage tank through a water pipeline; this structure can carry out electrolyte to electron sieve system oxygen module and supply, makes the system oxygen efficiency of electron sieve system oxygen module not influenced.

Description

Deoxidization locker with electrolyte complementary system

Technical Field

The utility model relates to a deoxidization locker field specifically is a deoxidization locker with electrolyte complementary system.

Background

At present, the nitrogen-containing fresh-keeping storage device is used for fresh-keeping storage (fresh keeping of dry goods, fruits, food and the like) and preservation storage (storage of valuables such as jewelry, collectibles and the like), generally only adopts a special and sealed box body for storage, or improves technical means such as vacuumizing a storage space, and the like, and even if nitrogen is used for preservation or preservation, nitrogen is only flushed into the storage space by a nitrogen tank and then sealed. The technical means has the defects of complex operation, high operation cost, complex operation and the like.

Therefore, the applicant proposes a structure of a storage system for self-generated nitrogen (patent number: CN201810942420. X) at 2018, 08 and 17, but the electronic sieve oxygen generation module gradually consumes the internal electrolyte during the use process, so that further improvement is needed for solving the electrolyte supplement problem.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to solve above-mentioned current problem, provide a simple structure, reasonable deoxidization locker with electrolyte make-up system, its effect can realize supplementing the function of electrolyte to the electron sieve system oxygen module through storage water tank and moisturizing case.

A deoxidizing storage cabinet with an electrolyte supplementing system comprises a cabinet body with a storage space, an electronic sieve oxygen generation module, a liquid storage tank, a water supplementing tank, a water storage tank and a dehumidifying device;

the electronic sieve oxygen generation module is provided with an air inlet end, an oxygen exhaust end and a liquid inlet end, and the air inlet end is communicated with the storage space;

a liquid storage cavity for storing electrolyte is arranged in the liquid storage tank, a liquid outlet end, a first water inlet end and a second water inlet end which are communicated with the liquid storage cavity are arranged on the liquid storage tank, and the liquid outlet end is communicated with a liquid inlet end of the electronic sieve oxygen production module;

the water replenishing tank is provided with a water replenishing port capable of being exposed outside the cabinet body, an oxygen inlet and a water outlet end, the water replenishing port is communicated with an inner cavity of the water replenishing tank, the oxygen inlet is communicated with an oxygen exhaust end of the electronic-sieve oxygen production module, the oxygen inlet is arranged below the liquid level of the water replenishing tank, and the water outlet end is communicated with a first water inlet end of the liquid storage tank through a first water suction pump;

the dehumidification device is communicated with the storage space, a water receiving box is arranged below the dehumidification device, and a drainage end is arranged on the water receiving box;

the water storage tank is provided with a water tank water inlet end and a water tank water outlet end, the water tank water inlet end is communicated with the water discharging end of the water receiving box and collects condensed water generated by the dehumidifying device, and the water tank water outlet end is communicated with the second water inlet end of the liquid storage tank through a second water suction pump.

The utility model discloses can also adopt following technical measure to solve:

further, a liquid level detection element connected with the first water suction pump and the second water suction pump is installed on the liquid storage tank, and the liquid level detection element at least comprises a high liquid level monitoring point, a middle liquid level detection point and a low liquid level detection point.

Further explaining, a hot air system and an evaporation device which are matched with the dehumidification device are also arranged on the cabinet body; the water storage tank is internally provided with a water storage cavity, the top of the water storage cavity is provided with a water level detector for detecting the high level liquid level of the water storage cavity, and the water storage tank is provided with a water replenishing end corresponding to the high level liquid level; the evaporation device is provided with a water inlet end, the water inlet end is communicated with a water supplementing end through a water supplementing pump, the water supplementing pump is connected with a water level detector, the evaporation device is installed at a hot air outlet of a hot air system, and hot air is blown out through the hot air system to accelerate water evaporation on the evaporation device.

Further, an air exhaust port is further formed in the electronic sieve oxygen production module, an air inlet communicated with the liquid storage cavity is further formed in the liquid storage box, and the air inlet is communicated with the air exhaust port through an air pipeline.

Further, the dehumidification device comprises a refrigeration sheet and a heat absorption fin which are arranged in the storage space, the heat absorption end surface of the refrigeration sheet faces the storage space and is in contact with air in the storage space, the heat absorption fin is arranged on the heat absorption end surface of the refrigeration sheet, the water receiving box is arranged below the heat absorption fin, and the water discharging end of the water receiving box extends out of the storage space.

Further, the hot air system comprises a fan and radiating fins, the radiating fins are connected to the radiating end faces of the refrigerating fins, a plurality of radiating air channels are formed in the radiating fins, the fan is installed on one side of each radiating air channel, an air outlet of the fan and the radiating air channels are arranged in the same direction, an air guide cover is installed on the other side of each radiating air channel, and the evaporation device is installed in the air guide cover.

Further explaining, the evaporation device comprises an evaporation box, a box inner cavity communicated with the water inlet end is formed in the evaporation box, absorbent cotton is flatly paved at the bottom of the box inner cavity, and a water blocking cover is detachably arranged in the box inner cavity corresponding to the water inlet end.

Further, the cabinet body comprises an inner container which limits a storage space, the electronic sieve oxygen generation module is attached to the side wall of the inner container, the side wall is provided with a plurality of communication ports which are communicated with the air inlet end of the electronic sieve oxygen generation module and the storage space, and the liquid storage box is arranged at the top of the inner container.

Further, an air exhaust end is arranged at the top of the water storage tank and communicated with the storage space.

Further explaining, an installation cavity C is arranged in the cabinet body, and the water replenishing tank is installed in the installation cavity C in a drawing mode; the water replenishing tank comprises a tank cover, the water replenishing port is formed in the tank cover and covered with a sealing cover, and an oxygen exhaust port communicated with an inner cavity of the water replenishing tank is formed in the tank cover.

The utility model has the advantages as follows:

the utility model discloses a deoxidization locker with electrolyte make-up system, moreover, the steam generator is simple in structure, low in use cost, assembly connection is convenient, but this structure can install the moisturizing case in the deoxidization locker with the pull of the mode of embedding, the user can carry out external moisturizing to the moisturizing case through the moisturizing mouth, and the comdenstion water that dehydrating unit produced flows into in the storage water tank, make the aqueous solution in storage water tank and the moisturizing case can flow into the liquid reserve tank and carry out the moisturizing to electron sieve system oxygen module, make electron sieve system oxygen module can keep good system oxygen efficiency, increase the life of electron sieve system oxygen module, the discarded object that can make in the deoxidization locker use produce is utilized once more, reduce the wasting of resources, and the energy utilization efficiency is improved.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic view of the electronic sieve oxygen generation module and the inner container decomposition structure of the present invention.

Fig. 3 is a schematic view of the exploded structure of the liquid storage tank of the present invention.

Fig. 4 is a schematic view of the local exploded structure of the present invention.

Fig. 5 is a schematic view of the decomposition structure of the water storage tank of the present invention.

Fig. 6 is a schematic view of the decomposition structure of the water replenishing tank of the present invention.

Fig. 7 is a schematic view of the electrolyte replenishing system of the present invention.

Detailed Description

The present invention will be further explained with reference to the drawings and examples.

As shown in figures 1 to 7, the deoxidization storage cabinet with the electrolyte supplementing system comprises a cabinet body 1 with a storage space A, an electronic sieve oxygen generation module 2, a liquid storage tank 3, a water supplementing tank 6, a water storage tank 4 and a dehumidifying device 5;

the electronic sieve oxygen production module 2 is provided with an air inlet end 21, an oxygen outlet end 22 and a liquid inlet end 23, and the air inlet end 21 is communicated with the storage space A;

a liquid storage cavity B for storing electrolyte is arranged in the liquid storage tank 3, a liquid outlet end 31, a first water inlet end 32 and a second water inlet end 33 which are communicated with the liquid storage cavity B are arranged on the liquid storage tank 3, and the liquid outlet end 31 is communicated with the liquid inlet end 23 of the electronic sieve oxygen production module 2;

the water replenishing tank 6 is provided with a water replenishing port 61 capable of being exposed outside the cabinet body, an oxygen inlet 62 and a water outlet 63, the water replenishing port 61 is communicated with an inner cavity of the water replenishing tank 6, the oxygen inlet 62 is communicated with the oxygen exhaust end 22 of the electronic-sieve oxygen production module 2, the oxygen inlet 62 is arranged below the liquid level of the water replenishing tank 6, and the water outlet 63 is communicated with the first water inlet 32 of the liquid storage tank 3 through a first water suction pump 7;

the dehumidification device 5 is communicated with the storage space A, a water receiving box 8 is arranged below the dehumidification device 5, and the water receiving box 8 is provided with a drainage end 81;

the water storage tank 4 is provided with a water tank water inlet end 41 and a water tank water outlet end 42, the water tank water inlet end 41 is communicated with the water discharge end 81 of the water receiving box 8 and collects condensed water generated by the dehumidifying device 5, and the water tank water outlet end 42 is communicated with the second water inlet end 33 of the liquid storage tank 3 through a second water suction pump 13.

But this structure can install the moisturizing case in the deoxidization locker with the mode pull of embedding, the user can carry out external moisturizing to moisturizing case 6 through moisturizing mouth 61, and the comdenstion water that dehydrating unit 5 produced flows into in the storage water tank, make the aqueous solution in storage water tank 4 and the moisturizing case 6 can flow into liquid reserve tank 3 and carry out the moisturizing to electron sieve system oxygen module 2, make electron sieve system oxygen module 2 can keep good system oxygen efficiency, increase electron sieve system oxygen module 2's life, the discarded object that can make the production in the deoxidization locker use is utilized once more, reduce the wasting of resources, the efficiency of energy utilization is improved.

The electronic sieve oxygen generation module 2 mainly comprises a deoxygenation membrane and electrolyte, oxygen in the air is adsorbed by the deoxygenation membrane and is discharged, the deoxygenation function is realized, in the process, the electrolyte in the electronic sieve oxygen generation module 2 can be gradually reduced along with the lapse of time, and the deoxygenation effect is ensured by timely supplementing.

The structure of the electronic sieve oxygen generation module belongs to the prior art, so detailed description is not provided herein, and specific reference is made to publication number CN210262023U (name: a universal electronic sieve oxygen generation module), which discloses the structure, application and principle of the electronic sieve oxygen generation module.

The oxygen-removing storage cabinet can inhibit bacteria and resist oxidation, so that the survival rate of microorganisms is reduced in an oxygen-free or low-oxygen state or even the microorganisms cannot survive, the insect-proof, moisture-proof, mildew-proof, corrosion-proof, oxidation-proof and fresh-keeping effects are high, pests and germs in the storage cabinet are effectively killed, the moisture removal can be realized to keep the inside of the storage cabinet dry, and in addition, the oxygen-removing storage cabinet can be a food storage cabinet and can also be used for storing other articles needing oxidation resistance and bacteria resistance, such as jewelry, files, important properties and the like.

A liquid level detection element 14 connected with the first water pump 7 and the second water pump 13 is installed on the liquid storage tank 3, and the liquid level detection element 14 at least comprises a high liquid level monitoring point, a middle liquid level detection point and a low liquid level detection point; the first water suction pump 7 or the second water suction pump 13 is controlled to work according to the liquid level height detected by the liquid level detecting element 7, the water storage tank 4 or the water replenishing tank 6 is used for replenishing water to the liquid storage tank 3, when the liquid level detecting element 7 detects that the liquid storage tank 3 is located at a middle liquid level detection point, the second water suction pump 13 is driven to work, condensed water in the water storage tank 4 is pumped into the liquid storage tank 3, when the liquid level detecting element 7 detects that the liquid storage tank 3 is located at a low liquid level detection point, namely, the water in the water storage tank 4 can be pumped, the first water suction pump 7 is controlled to work, electrolyte in the water replenishing tank 6 is pumped into the liquid storage tank 3 at one time, and the liquid level of the liquid storage tank 3 reaches the middle liquid level detection point.

The cabinet body 1 is also provided with a hot air system 9 and an evaporation device 10 which are matched with the dehumidification device 5; a water storage cavity 4a is arranged in the water storage tank 4, a water level detector 11 for detecting the high level of the water storage cavity 4a is arranged at the top of the water storage tank 4, and a water replenishing end 43 is arranged on the water storage tank 4 corresponding to the high level; the evaporation device 10 is provided with a water inlet end 1001, the water inlet end 1001 is communicated with the water replenishing end 43 through a water replenishing pump 12, the water replenishing pump 12 is connected with the water level detector 11, the evaporation device 10 is installed at a hot air outlet of the hot air system 9, and hot air is blown out through the hot air system 9 to accelerate water evaporation on the evaporation device 10; the water storage tank 4 and the liquid storage tank 3 are fully loaded through a hot air system 9 and an evaporation device 10, and redundant condensed water is evaporated.

The electronic sieve oxygen generation module 2 is further provided with an air exhaust port 24, the liquid storage tank 3 is further provided with an air inlet 34 communicated with the liquid storage cavity B, the air inlet 34 is communicated with the air exhaust port 24, the air inlet 34 and the air exhaust port 24 enable air in the electronic sieve oxygen generation module 2 and air in the liquid storage cavity B to form a loop, and the electronic sieve oxygen generation module 2 and the liquid storage tank 3 are both sealed spaces, so when the liquid storage tank 3 replenishes the electronic sieve oxygen generation module 2, air in the electronic sieve oxygen generation module 2 can flow into the liquid storage cavity B through an air pipeline, air pressure in the liquid storage cavity B and a water-vapor separation cavity of the electronic sieve oxygen generation module 2 is effectively kept balanced and stable, oxygen can be further guaranteed to be normally conveyed constantly, oxygen supply requirements of users are met, use and embodiment of users are improved, and air in the water-vapor separation cavity has alkaline ions, after flowing into the liquid storage cavity B, the solution is generated, and the concentration of the electrolyte is improved.

The dehumidifying device 5 comprises a refrigerating sheet 501 and a heat absorbing fin 502 which are arranged in the storage space A, the heat absorbing end surface of the refrigerating sheet 501 faces the storage space A and is in contact with the air in the storage space A, the heat absorbing fin 502 is installed on the heat absorbing end surface of the refrigerating sheet 501, the water receiving box 8 is arranged below the heat absorbing fin 502, and the water discharging end 81 of the water receiving box 8 extends out of the storage space A; utilize the physical characteristic that air contact low temperature terminal surface produced the comdenstion water to realize dehumidifying, because storage space A is in encapsulated situation for a long time, consequently storage space A's moisture can reduce gradually, and the humidity that reaches storage space A satisfies the storage demand.

The hot air system 9 comprises a fan 91 and radiating fins 92, the radiating fins 92 are connected to the radiating end surfaces of the refrigerating fins 501, a plurality of radiating air channels 921 are arranged in the radiating fins 92, the fan 91 is installed on one side of each radiating air channel 921, an air outlet 911 of the fan 91 is arranged in the same direction as the radiating air channels 921, an air guide cover 93 is installed on the other side of each radiating air channel 921, and the evaporation device 10 is installed in the air guide cover 93; the hot air system 9 with the structure can radiate the heat of the dehumidifier 5 on one hand, and can form hot air to evaporate condensed water on the other hand, thereby fully utilizing waste heat and reducing heat energy waste.

A plurality of air exhaust holes 103 are formed in the cabinet body 1 corresponding to the heat dissipation fins 92 and the air guide cover 93, and an air guide surface 931 inclined to the air exhaust holes 103 is arranged on one side of the air guide cover 93 away from the fan 91; the air with moisture and heat can be discharged out of the cabinet body, and the damage of accessories caused by staying in the cabinet body is prevented.

The evaporation device 10 comprises an evaporation box 1002, an inner cavity 1003 communicated with a water inlet end 1001 is arranged in the evaporation box 1002, absorbent cotton 1004 is flatly paved at the bottom of the inner cavity 1003, and a water retaining cover 1005 is detachably arranged in the inner cavity 1003 corresponding to the water inlet end 1001.

The water inlet end 1001 of the evaporation device 10 is arranged at the bottom of the evaporation box 1002, when the water replenishing pump 12 pumps condensed water into the box inner cavity 1003, the water absorption cotton 1004 absorbs water, the condensed water is rapidly dispersed, the area of the condensed water contacting air is increased to the maximum extent, the evaporation speed is improved, and the condensed water is pumped into the box inner cavity 1003 from bottom to top, so that when the water flow is large, the water can upwards flush out of the upper part of the evaporation box 1002, other positions are splashed out, other parts of the cabinet are easily damaged, the water flow can be shielded through the water shielding cover 1005, and the condensed water is prevented from flowing back to the water absorption cotton 1004 in the box inner cavity 1003.

The working process of the electrolyte supplementing system in the deoxidizing storage cabinet is specifically as follows:

the first process is as follows: the electronic sieve oxygen generation module 2 is used for deoxidizing the storage space A;

oxygen in the electron sieve system oxygen module 2 can adsorb the air in the use, makes storage space A's oxygen reduce through discharging this partial oxygen, and at the in-process of adsorbing oxygen, the electrolyte in the electron sieve system oxygen module 2 can reduce gradually, and in wherein the oxygen of production can flow into moisturizing case 6 through the trachea, filters through the aqueous solution in moisturizing case 6, makes the alkaline ion that has in the oxygen melt into the aqueous solution and turn into the electrolyte that the concentration is lower gradually.

And a second process: the dehumidifying device 5 dehumidifies the storage space a;

process two and process one can go on successively, perhaps go on simultaneously, specifically, the heat that absorbs heat fin 502 is absorbed to the heat absorption terminal surface of refrigeration piece 501, makes behind the air contact heat absorption fin 502 in the storage space A, moisture is at the surperficial comdenstion water of heat absorption fin 502, and the comdenstion water drips into water receiving box 8, then along the water pipeling in flowing into storage water tank 4, storage water tank 4 deposit comdenstion water is used for the moisturizing effect of storage tank 3.

The third process: the liquid storage tank 3 replenishes the electronic sieve oxygen generation module 2 with electrolyte;

in process one, electron sieve system oxygen module 2 is at the oxygen process, the electrolyte in the electron sieve system oxygen module 2 can reduce gradually, consequently make the electrolyte in the electron sieve system oxygen module 2 can supply through being connected with liquid reserve tank 3, and electron sieve system oxygen module 2 when the assembly, the liquid reserve tank 3 of great capacity and storage water tank 4 all encapsulate at the cabinet body 1, the user can not dismantle the cabinet body when needs moisturizing, consequently in process of production, fill electrolyte to liquid reserve tank 3 earlier, when making the deoxidization locker use in earlier stage, have sufficient electrolyte to supply into in the electron sieve system oxygen module 2, guarantee the system oxygen effect of electron sieve system oxygen module 2, but can not directly supply electrolyte or aqueous solution to liquid reserve tank 3.

The process four is as follows: the water storage tank 4 is used for supplementing condensed water to the liquid storage tank 3;

because the capacity of liquid reserve tank 3 is limited, and can not directly annotate liquid reserve tank 3 with electrolyte, consequently when the well liquid level check point that triggers liquid level detection element 14 on liquid reserve tank 3, liquid level detection element 14 drive second suction pump 13 work, when the comdenstion water suction in the storage water tank 4 reaches the high liquid level check point that triggers liquid level detection element 14 in liquid reserve tank 3, or detect that second suction pump 13 is in no load during operation again (storage water tank 4 does not have water and can pump), even storage tank 3 does not reach the high liquid level check point, still stop second suction pump 13 work, this process makes the comdenstion water can recycle.

And a fifth process: the water replenishing tank 6 replenishes the liquid storage tank 3 with pure water or tap water;

in the fourth process, when the humidity in the storage space a is reduced or when dehumidification is not needed, the condensate water generated by the dehumidification device 5 is reduced, even the water storage tank 4 does not have condensate water, when the liquid level in the water storage tank 3 is gradually reduced to the low liquid level detection point of the liquid level detection element 14 after long-term use, the water storage tank 4 is judged to be temporarily free of water and can be supplied to the water storage tank 3, at the moment, the liquid level detection element 14 drives the first water suction pump 7 to work, the pure water in the water replenishing tank 6 is converted into the electrolyte with low concentration and is pumped into the water storage tank 3, the first water suction pump 7 is stopped to work until the liquid level in the water storage tank 3 triggers the middle liquid level detection point of the liquid level detection element 14 or the water replenishing tank 6 is pumped out, and the buffer process enables the water storage tank 4 to have enough time to replenish the condensate water generated by the dehumidification device 5.

The process six: supplying pure water or tap water to the water supply tank 6;

electrolyte in moisturizing case 6 is behind by suction liquid reserve tank 3, the user finds 6 low backs of moisturizing case water level through observing moisturizing case 6, in time moisturizing 6 is carried out to moisturizing case through moisturizing mouth 61, even storage water tank 4 still does not have when water can take out, moisturizing case 6 still carries out the moisturizing to storage water tank 3, consequently can be provided with visual window on moisturizing case 6, a liquid level for observing moisturizing case 6, in addition can also observe the oxygen gassing condition of oxygen air inlet 62, the deoxidization locker deoxidization condition is observed directly perceivedly.

The process is seven: draining the excess condensate water in the water storage tank 4;

when the electronic sieve oxygen generation module 2 does not need to supplement electrolyte, the liquid storage tank 3 and the water storage tank 4 are in a high liquid level state, and the deoxidizing storage cabinet still continues to dehumidify the storage space a, when the condensed water liquid level collected in the water storage tank 4 is higher than the water outlet end 42 of the water tank to the highest liquid level, the water level detector 11 is triggered, the water supplementing pump 12 is driven to work to pump a small amount of condensed water in the water storage tank 4 to the box inner cavity 1003 of the evaporation box 1002 (for example, 20ML at each time), so that the absorbent cotton 1004 in the box inner cavity 1003 absorbs the condensed water, the condensed water is dispersed, and the area of the condensed water contacting air is increased.

And the process eight: evaporating the redundant condensed water in the water storage tank 4;

after unnecessary comdenstion water suction box cavity 1003, radiating fin 92 absorbs the heat of the cooling terminal surface of refrigeration piece 501, and the air outlet 911 of fan 91 is just to radiating fin 92's heat dissipation wind channel 921, the air flows through heat dissipation wind channel 921 and takes away the heat of refrigeration piece 501 and realizes the heat dissipation, and form hot-blastly, hot-blastly blow the cotton 1004 that absorbs water and make the evaporation of water and take out the cabinet body, in the evaporation process, when moisturizing pump 12 detects out when not having the load state (no water can be taken out), judge that the water level in the storage water tank 4 is less than moisturizing end 43, moisturizing pump 12 stop work, this settlement guarantees that the water volume that can deposit in the storage water tank 4 and be close to full load supplies liquid reserve tank 3 to use, and the storage water tank 4 overflow problem can not appear.

The cabinet body 1 comprises an inner container 101 for limiting a storage space, the electronic sieve oxygen generation module 2 is attached to the side wall of the inner container 101, the side wall is provided with a plurality of communication ports 102 for communicating an air inlet end 21 of the electronic sieve oxygen generation module 2 with the storage space A, and the liquid storage tank 3 and the water replenishing tank 6 are both arranged at the top of the inner container 101; the position of installing liquid reserve tank 3 is higher than electronic sieve system oxygen module 2, can make the electrolyte in the liquid reserve tank 3 can flow into electronic sieve system oxygen module 2 automatically, need not set up the pump body and carry out mechanical fluid infusion.

Install two electron sieve system oxygen module 2 on the lateral wall about inner bag 101, liquid reserve tank 3 corresponds two electron sieve system oxygen module 2 and is provided with two liquid ends 31, two liquid ends 31 communicate corresponding feed liquor end 23 separately, two oxygen exhaust ends 22 pass through the oxygen air inlet 62 intercommunication of three-way pipe 16 with moisturizing case 6, perhaps two oxygen air inlets 62 have been seted up to two oxygen exhaust ends 22 on the moisturizing case, two electron sieve system oxygen module 2 can improve the efficiency of storage space deoxidization to produce in the sufficient oxygen arranges moisturizing case 6.

The top of the water storage tank 4 is provided with an air exhaust end 44, and the air exhaust end 44 is communicated with the storage space A; when water receiving box 8 discharges the comdenstion water toward storage water tank 4, sealed storage water tank 4 need outside exhaust air, and with the air-discharge storage space A in, can guarantee the leakproofness in the storage space A at the deoxidization in-process, prevent that the oxygen content in the storage space A from resumeing into in the storage space A through storage water tank 4, causes the storage space A to restore.

An installation cavity C is formed in the cabinet body 1, and the water replenishing tank 6 is installed in the installation cavity C in a drawing mode; the water replenishing tank 6 comprises a tank cover 601, the water replenishing port 61 is arranged on the tank cover 601 and covered with a sealing cover 602, and the tank cover 601 is also provided with an oxygen exhaust port 603 communicated with the inner cavity of the water replenishing tank 6;

when moisturizing, the user can make the moisturizing mouth 61 on the moisturizing case 6 expose through taking out the moisturizing case 6, then add water in external connection, add water and finish the back and push into installation cavity C with moisturizing case 6 again, be convenient for hide storage water tank 4, make the deoxidization locker more pleasing to the eye.

A protective cover 15 is arranged in the storage space A corresponding to the heat absorbing fins 502, and a plurality of communicating holes 1501 are formed in the protective cover 15; the heat absorbing fins 502 can be protected from damage caused by an object placed in the storage space a colliding against the heat absorbing fins 502.

Offer one time filling opening 301 on the liquid reserve tank 3, be connected with spiral cover 302 on one time filling opening 301, during production assembly, the workman can seal more firmly through spiral cover 302 and establish one time filling opening 301 in pouring into liquid reserve tank 3 with electrolyte through one time filling opening 301, avoids transporting the weeping problem in the handling.

The foregoing is a preferred embodiment of the present invention showing and describing the basic principles, main features and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are intended to illustrate the principles of the invention, but rather that various changes and modifications may be made without departing from the spirit and scope of the invention, the scope of which is defined by the appended claims and their equivalents.

Claims (10)

1. A deoxidization locker with electrolyte replenishment system, includes the cabinet body (1) that has storage space (A), its characterized in that: the device also comprises an electronic sieve oxygen generation module (2), a liquid storage tank (3), a water supplementing tank (6), a water storage tank (4) and a dehumidifying device (5);

the electronic sieve oxygen generation module (2) is provided with an air inlet end (21), an oxygen exhaust end (22) and a liquid inlet end (23), and the air inlet end (21) is communicated with the storage space (A);

a liquid storage cavity (B) for storing electrolyte is arranged in the liquid storage tank (3), a liquid outlet end (31), a first water inlet end (32) and a second water inlet end (33) which are communicated with the liquid storage cavity (B) are arranged on the liquid storage tank (3), and the liquid outlet end (31) is communicated with a liquid inlet end (23) of the electronic sieve oxygen production module (2);

the water replenishing tank (6) is provided with a water replenishing port (61) capable of being exposed outside the cabinet body, an oxygen inlet (62) and a water outlet end (63), the water replenishing port (61) is communicated with an inner cavity of the water replenishing tank (6), the oxygen inlet (62) is communicated with an oxygen exhaust end (22) of the electronic sieve oxygen generation module (2), the oxygen inlet (62) is arranged below the liquid level of the water replenishing tank (6), and the water outlet end (63) is communicated with a first water inlet end (32) of the liquid storage tank (3) through a first water suction pump (7);

the dehumidification device (5) is communicated with the storage space (A), a water receiving box (8) is mounted below the dehumidification device (5), and the water receiving box (8) is provided with a drainage end (81);

be provided with on storage water tank (4) that the water tank is intake end (41) and water tank and go out water end (42), the water tank is intake end (41) and drainage end (81) intercommunication of water receiving box (8) and is collected the comdenstion water that dehydrating unit (5) produced, the water tank is gone out water end (42) and the second of liquid reserve tank (3) and is intake and hold (33) between through second suction pump (13) intercommunication.

2. The oxygen-removing storage cabinet with the electrolyte replenishing system according to claim 1, wherein: install liquid level detection element (14) with first suction pump (7) and the hookup of second suction pump (13) on liquid reserve tank (3), liquid level detection element (14) include high liquid level monitoring point, well liquid level check point and low liquid level check point at least.

3. The oxygen-removing storage cabinet with the electrolyte replenishing system according to claim 1, wherein: the cabinet body (1) is also provided with a hot air system (9) and an evaporation device (10) which are matched with the dehumidification device (5); a water storage cavity (4a) is arranged in the water storage tank (4), a water level detector (11) for detecting the high-level liquid level of the water storage cavity (4a) is installed at the top of the water storage cavity, and a water replenishing end (43) is arranged on the water storage tank (4) corresponding to the high-level liquid level; the evaporation device (10) is provided with a water inlet end (1001), the water inlet end (1001) is communicated with a water supplementing end (43) through a water supplementing pump (12), the water supplementing pump (12) is connected with a water level detector (11), the evaporation device (10) is installed at a hot air outlet of a hot air system (9), and hot air is blown out through the hot air system (9) to accelerate water evaporation on the evaporation device (10).

4. The oxygen-removing storage cabinet with the electrolyte replenishing system according to claim 1, wherein: the electronic sieve oxygen generation module (2) is further provided with an air exhaust port (24), the liquid storage box (3) is further provided with an air inlet (34) communicated with the liquid storage cavity (B), and the air inlet (34) is communicated with the air exhaust port (24).

5. The oxygen-scavenging storage cabinet with the electrolyte replenishing system according to claim 3, wherein: dehumidification device (5) are including setting up refrigeration piece (501) and endothermic fin (502) in storage space (A), the heat absorption terminal surface of refrigeration piece (501) contacts towards the air in storage space (A) and the storage space (A), heat absorption fin (502) are installed on the heat absorption terminal surface of refrigeration piece (501), water receiving box (8) set up the below at heat absorption fin (502), and outside water drainage end (81) of water receiving box (8) extended storage space (A).

6. The oxygen-scavenging storage cabinet with the electrolyte replenishing system according to claim 5, wherein: the hot air system (9) comprises a fan (91) and radiating fins (92), the radiating fins (92) are connected to the radiating end face of the refrigerating sheet (501), a plurality of radiating air ducts (921) are arranged in the radiating fins (92), the fan (91) is installed on one side of each radiating air duct (921), an air outlet (911) of the fan (91) and the corresponding radiating air duct (921) are arranged in the same direction, an air guide cover (93) is installed on the other side of each radiating air duct (921), and the evaporation device (10) is installed in the air guide cover (93).

7. The oxygen-scavenging storage cabinet with the electrolyte replenishing system according to claim 3, wherein: the evaporation device (10) comprises an evaporation box (1002), a box inner cavity (1003) communicated with the water inlet end (1001) is formed in the evaporation box (1002), absorbent cotton (1004) is flatly paved at the bottom of the box inner cavity (1003), and a water blocking cover (1005) is detachably installed in the box inner cavity (1003) corresponding to the water inlet end (1001).

8. The oxygen-removing storage cabinet with the electrolyte replenishing system according to claim 1, wherein: the cabinet body (1) is including injecing inner bag (101) of storage space, electron sieve system oxygen module (2) are by pasting and install on the lateral wall of inner bag (101), set up a plurality of intercommunication mouth (102) of air inlet end (21) and storage space (A) of intercommunication electron sieve system oxygen module (2) on the lateral wall, the top at inner bag (101) is all installed in liquid reserve tank (3) and moisturizing case (6).

9. The oxygen-removing storage cabinet with the electrolyte replenishing system according to claim 1, wherein: the top of the water storage tank (4) is provided with an air exhaust end (44), and the air exhaust end (44) is communicated with the storage space (A).

10. The oxygen-removing storage cabinet with the electrolyte replenishing system according to claim 1, wherein: an installation cavity (C) is formed in the cabinet body (1), and the water replenishing tank (6) is installed in the installation cavity (C) in a drawing mode; the water replenishing tank (6) comprises a tank cover (601), the water replenishing port (61) is formed in the tank cover (601) and covered with a sealing cover (602), and an oxygen exhaust port (603) communicated with an inner cavity of the water replenishing tank (6) is formed in the tank cover (601).

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