CN114279146B - Intelligent freezer that possesses humidity control - Google Patents

Abstract

The invention relates to the field of refrigeration houses, in particular to an intelligent refrigeration house with humidity adjustment. Technical problems: the humidity in the refrigeration house can not be adjusted in time by the existing refrigeration house, and meanwhile, the oxygen content in the refrigeration house can be increased, so that the respiration of vegetables and fruits is aggravated. The technical implementation scheme of the invention is as follows: an intelligent refrigeration house with humidity regulation comprises an assembled house body, a dehumidifying system and the like; the right side of the rear part of the assembled warehouse body is connected with a dehumidifying system for removing redundant water molecules in the refrigerator. According to the invention, the humidity in the refrigerator is monitored in real time, the water molecules are driven to flow by pumping the air in the refrigerator, then the water molecules in the refrigerator are sucked and filtered by utilizing the water absorbing substances, and meanwhile, the excessive entering of the external air into the refrigerator is reduced, so that the content of carbon dioxide in the refrigerator is kept at a higher level, the respiration of vegetables and fruits in the refrigerator can be effectively inhibited, the consumption of organic substances in the vegetables and fruits is reduced, and the fresh-keeping quality is truly improved.

Description

Intelligent freezer that possesses humidity control

Technical Field

The invention relates to the field of refrigeration houses, in particular to an intelligent refrigeration house with humidity adjustment.

Background

The refrigerator is actually a low-temperature combined air conditioner, and compared with the refrigerator, the refrigerator has a much larger refrigerating area, but the refrigerating principle is communicated.

When vegetables and fruits are placed in the refrigeration house for refrigeration, water molecules generated by respiration in the vegetables and fruits are discharged by the transpiration effect to increase the humidity of the refrigeration house, so that a large amount of frosting is generated in the refrigeration house, the humidity in the refrigeration house cannot be timely adjusted by the existing refrigeration house, the problem that the humidity in the refrigeration house is too high is difficult to solve by utilizing an exhaust mode, meanwhile, the oxygen content in the refrigeration house can be increased, the respiration of the vegetables and fruits is aggravated, and the quality of the vegetables and fruits is affected.

To the above problems, an intelligent refrigerator with humidity adjustment is proposed.

Disclosure of Invention

In order to overcome the defect that the existing refrigeration house cannot timely adjust the humidity in the refrigeration house, and meanwhile the oxygen content in the refrigeration house is increased to aggravate the respiration of vegetables and fruits, the invention provides an intelligent refrigeration house with humidity adjustment.

The technical implementation scheme of the invention is as follows: an intelligent refrigeration house with humidity regulation comprises an assembled house body, a sliding rail, an electric control moving block, a protective door, refrigeration equipment, a humidity sensor, a heat preservation system and a dehumidification system; the front part of the upper surface of the spliced warehouse body is connected with a sliding rail; the slide rail is connected with two electric control moving blocks in a sliding way; two electric control moving blocks are fixedly connected with a protective door respectively; the rear part of the spliced warehouse body is connected with refrigeration equipment; two humidity sensors are respectively connected with the left side surface and the right side surface inside the spliced library body; the upper side of the left part and the lower side of the right part of the spliced warehouse body are respectively connected with a heat preservation system for preventing cold air from flowing to the outside; the right side of the rear part of the spliced warehouse body is connected with a dehumidifying system for removing superfluous water molecules in the refrigerator; the two heat preservation systems are connected with the dehumidification system.

More preferably, the heat preservation system comprises a first L-shaped supporting plate, an air box, a rotating motor, a third rotating shaft, a third heat insulation plate, a fourth heat insulation plate and a fifth heat insulation plate; the upper side of the left part and the lower side of the right part of the spliced library body are fixedly connected with a first L-shaped supporting plate respectively; the upper parts of the two first L-shaped supporting plates are fixedly connected with an air box respectively; the two bellows are connected with a heat preservation system; the front parts of the two bellows are fixedly connected with a rotating motor respectively; a third rotating shaft is rotatably connected in each of the two bellows; the output shafts of the two rotating motors are fixedly connected with a third rotating shaft respectively; a third heat insulation plate is fixedly connected on each of the two third rotating shafts; the upper surfaces of the inner parts of the two bellows are fixedly connected with a fifth heat insulation plate respectively; the lower surfaces of the inner parts of the two bellows are fixedly connected with a fourth heat insulation plate respectively.

More preferably, the dehumidification system comprises a support frame, a first guide pipe, a second L-shaped support plate, a fan, a water molecule removing mechanism and a second guide pipe; the upper side of the rear part of the spliced warehouse body is fixedly connected with a supporting frame; the support frame is fixedly connected with a first guide pipe; the first guide pipe is arranged on the left bellows in a penetrating way; the lower side of the rear part of the spliced warehouse body is fixedly connected with a second L-shaped supporting plate; a fan is fixedly connected on the second L-shaped supporting plate; the air inlet of the fan is fixedly connected with a first guide pipe; the lower side of the rear part of the spliced warehouse body is fixedly connected with a water molecule removing mechanism, and the water molecule removing mechanism is positioned on the right of the fan; the air outlet of the fan is fixedly connected with a water molecule removing mechanism; the right part of the water molecule removing mechanism is connected with a second guide pipe; the second guide pipe is arranged on the right bellows in a penetrating way.

More preferably, the water molecule removing mechanism comprises a connecting seat, a fixed cover, a rotating cover, a punching shell, a first fixed plate, a second servo motor, a second flat gear, a first dust collection net, a second fixed plate, a connecting frame, a bearing box, a bearing door and a third flat gear; a connecting seat is fixedly connected to the lower side of the rear part of the spliced warehouse body, and the connecting seat is positioned on the right side of the fan; a fixed cover is fixedly connected on the connecting seat; the upper part of the fixed cover is rotatably connected with a rotary cover; the right part of the fixed cover is fixedly connected with an expanding shell; the inner side of the right part of the fixed cover is fixedly connected with a second dust collection net; the left part of the fixed cover is fixedly connected with a first dust collection net; the first dust collection net is connected with an air outlet of the fan; two symmetrical second fixing plates are fixedly connected to the fixing cover; a connecting frame is fixedly connected to each of the two second fixing plates; a bearing box is fixedly connected between the two connecting frames; the bearing box is rotationally connected with a bearing door; a third flat gear is fixedly connected on the right connecting frame; the rear side of the right part of the spliced warehouse body is fixedly connected with a first fixing plate; a second servo motor is fixedly connected to the first fixed plate; the output shaft of the second servo motor is fixedly connected with a second flat gear; the output shaft of the second servo motor is rotationally connected with the fixed cover; the second flat gear is meshed with the third flat gear.

More preferably, the fixed cover is internally fixedly connected with two flow shrinkage rings for intensively flowing the air flow into the bearing box.

More preferably, the inner side of the carrying case is provided with a plurality of small holes for improving the absorption of water molecules.

More preferably, the device further comprises an identifier; the front parts of the two protection doors are respectively provided with a recognizer with fingerprint and face recognition.

More preferably, an insulation system is also included; the front side of the interior of the spliced warehouse body is connected with an isolation system; the isolation system comprises a first rotating shaft, a first servo motor, a sliding block, a connector and a folding mechanism; the upper side of the inside of the assembly warehouse body is provided with a chute, and three sliding blocks are connected in the chute in a sliding way; the front side of the left surface inside the spliced library body is rotationally connected with a first rotating shaft; the left part of the upper surface of the spliced library body is fixedly connected with a first servo motor; the output shaft of the first servo motor is fixedly connected with a first rotating shaft; the first rotating shaft is connected with a folding mechanism; the two sliding blocks on the right are connected with a folding mechanism; two connectors are sleeved between the two folding mechanisms; the left folding mechanism is connected with the leftmost sliding block.

More preferably, the right folding mechanism and the left folding mechanism are arranged in a mirror image mode; the folding mechanism comprises a first heat insulation plate, a second rotating shaft and a first flat gear; a first heat insulation plate is fixedly connected on the first rotating shaft; the left sliding block is rotationally connected with a second rotating shaft; the middle sliding block is rotationally connected with a second rotating shaft; the right sliding block is rotationally connected with a second rotating shaft; the right part of the first heat insulation plate is rotationally connected with a second heat insulation plate; the right part of the second heat insulation plate is rotationally connected with a second rotating shaft at the left side; the upper part of the left second rotating shaft is fixedly connected with a first flat gear; the outer surfaces of two adjacent second rotating shafts on the left are sleeved with two connectors; the upper part of the middle second rotating shaft is fixedly connected with a first flat gear; the left first flat gear is meshed with the right first flat gear; the right first heat insulation plate is rotationally connected with the rightmost second rotating shaft; the first right heat insulating plate is rotationally connected with the second right heat insulating plate.

More preferably, the air exhaust system is also included; the right upper side of the rear part of the spliced warehouse body is connected with an exhaust system; the exhaust system comprises a fixed box, a rear cover, an exhaust pipe, a third dust collection net, a turbine, an electric telescopic piece, a third fixed plate and a sixth heat insulation plate; two fixing boxes are fixedly connected to the right upper side of the rear part of the spliced warehouse body; the rear parts of the two fixed boxes are fixedly connected with a rear cover respectively; the two rear covers are provided with an exhaust pipe in a penetrating way; two third dust collection nets are fixedly connected to the rear sides of the inner parts of the two fixed boxes respectively; two impellers are fixedly connected in the two fixing boxes respectively, and the four impellers are positioned in front of the corresponding third dust collection net; the right upper side of the rear part of the assembled warehouse body is fixedly connected with two electric telescopic parts, and the two fixing boxes are positioned between the two electric telescopic parts; the telescopic parts of the two electric telescopic parts are fixedly connected with a third fixing plate; four sixth heat insulation plates are fixedly connected to the bottom of the third fixing plate.

Compared with the prior art, the invention has the following advantages: according to the method, the humidity in the refrigerator is monitored in real time, water molecules are driven to flow by pumping air in the refrigerator, then water molecules in the refrigerator are sucked and filtered by utilizing water absorbing substances, and meanwhile, the excessive entering of external air into the refrigerator is reduced, so that the content of carbon dioxide in the refrigerator is kept at a higher level, the respiration of vegetables and fruits in the refrigerator can be effectively inhibited, the consumption of organic substances in the vegetables and fruits is reduced, and the fresh-keeping quality is truly improved; meanwhile, when the goods are loaded and taken, the arrangement of the to-be-transferred area is utilized, so that excessive contact between air in the refrigeration house and external air is avoided, and the loss of cold air is reduced.

Drawings

FIG. 1 is a schematic diagram of a first three-dimensional structure of an intelligent refrigerator with humidity adjustment according to the present invention;

FIG. 2 is a schematic diagram of a second perspective structure of the intelligent refrigerator with humidity adjustment according to the present invention;

FIG. 3 is a schematic view of a first partial structure of an intelligent refrigerator with humidity regulation according to the present invention;

FIG. 4 is a schematic diagram of a second partial structure of the intelligent refrigerator with humidity adjustment according to the present invention;

FIG. 5 is an enlarged view of the G region of the present invention;

FIG. 6 is a schematic view of a third partial structure of the intelligent refrigerator with humidity adjustment according to the present invention;

FIG. 7 is a schematic perspective view of a thermal insulation system according to the present invention;

FIG. 8 is a cross-sectional view of the insulation system of the present invention;

FIG. 9 is a schematic view of a third partial structure of an intelligent refrigerator with humidity regulation according to the present invention;

FIG. 10 is a schematic view showing a first perspective structure of the water molecule removal mechanism of the present invention;

FIG. 11 is a schematic view showing a second perspective structure of the water molecule removal mechanism of the present invention;

FIG. 12 is an exploded view of the water molecule removal mechanism of the present invention;

FIG. 13 is a schematic view of a first perspective structure of an isolation system according to the present invention;

fig. 14 is a schematic diagram of a first perspective structure of the insulation system of the present invention.

The marks of the components in the drawings are as follows: 1-base, 2-assembled warehouse body, 3-slide rail, 4-electric control moving block, 5-protective door, 6-identifier, 7-refrigeration equipment, 8-humidity sensor, 101-first rotating shaft, 102-first servo motor, 103-first heat insulation plate, 104-second heat insulation plate, 105-second rotating shaft, 106-first flat gear, 107-slide block, 108-connector, 201-first L-shaped support plate, 202-bellows, 203-rotating motor, 204-third rotating shaft, 205-third heat insulation plate, 206-fourth heat insulation plate, 207-fifth heat insulation plate, 301-support frame, 302-first guide pipe, 303-second L-shaped support plate, 304-fan, 305-hydrone remove mechanism, 3051-connecting seat, 3052-fixed cover, 3053-rotating cover, 3054-expanded shell, 3055-first fixed plate, 3056-second servo motor, 3057-second flat gear, 3058-first dust collection net, 3059-second dust collection net, 30510-second fixed plate, 3053-connecting frame, 30512-carrying case, 3053-carrying door, 3059-third flat gear, 306-second honeycomb duct, 401-fixed case, 402-back cover, 403-exhaust duct, 404-third dust collection net, 405-impeller, 406-electric telescopic piece, 407-third fixed plate, 408-sixth heat insulation plate.

Detailed Description

The following description of the technical solutions in the embodiments of the present invention will be clear and complete, and it is obvious that the described embodiments are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In an embodiment of the present invention, the motorized telescopic member 406 is a cylinder.

Example 1

1-2 and 6, the intelligent refrigerator with humidity adjustment comprises an assembled refrigerator body 2, a sliding rail 3, an electric control moving block 4, a protective door 5, refrigeration equipment 7, a humidity sensor 8, a heat preservation system and a dehumidification system; the front part of the upper surface of the spliced warehouse body 2 is connected with a sliding rail 3; the slide rail 3 is connected with two electric control moving blocks 4 in a sliding way; two electric control moving blocks 4 are fixedly connected with a protective door 5 respectively; the rear part of the assembled warehouse body 2 is connected with a refrigeration device 7; the left side surface and the right side surface inside the spliced warehouse body 2 are respectively connected with two humidity sensors 8; the upper side of the left part and the lower side of the right part of the spliced warehouse body 2 are respectively connected with a heat preservation system; the right side of the rear part of the spliced warehouse body 2 is connected with a dehumidifying system; the two heat preservation systems are connected with the dehumidification system.

Also comprises an identifier 6; a recognizer 6 having fingerprint and face recognition is installed at the front of each of the two protection doors 5.

The method comprises the steps that an assembled warehouse body 2 is built on a flat substrate 1, a region to be transferred is built in the assembled warehouse body 2, mobile equipment isolating cold air flow is installed in the region to be transferred, before an intelligent refrigerator with humidity adjustment is used, the intelligent refrigerator is powered on, an intelligent control system is carried on the intelligent refrigerator, high-temperature refrigerated objects such as vegetables and fruits are placed in front of two protection doors 5, then a worker acquires use permission on an identifier 6, the controller controls two electric control moving blocks 4 to move on a sliding rail 3 in a back-to-back mode after permission confirmation is acquired, at the moment, the two electric control moving blocks 4 respectively drive one protection door 5 to be opened, then the worker pushes the refrigerated objects to the region to be transferred of the intelligent refrigerator, then the two protection doors 5 are closed, a controllable switch of the region to be transferred is opened, then the worker pushes the goods to a storage area of the refrigerator, and then the worker walks out of the refrigerator; then, the refrigeration equipment 7 is opened to start refrigerating the assembled warehouse body 2, the four humidity sensors 8 are kept in the running state all the time, the four humidity sensors 8 transmit humidity information in the assembled warehouse body 2 to the controller, when the humidity in the assembled warehouse body 2 is overlarge, the two heat preservation systems are controlled to run, the two heat preservation systems are opened, a channel capable of supplying air to flow is connected in the assembled warehouse body 2, meanwhile, the dehumidification system is started to run, the dehumidification system pumps air in the assembled warehouse body 2, the air flow drives water molecules in the air to flow, at the moment, the dehumidification system absorbs and filters the water molecules in the assembled warehouse body by utilizing water absorbing substances, and meanwhile, the condition that the excessive outside air enters the assembled warehouse body 2 is reduced, so that the content of carbon dioxide in the assembled warehouse body 2 is kept at a higher level, the respiration of vegetables and fruits in the assembled warehouse body 2 can be effectively inhibited, the consumption of organic substances in the vegetables and fruits is reduced, and the fresh-keeping quality is truly improved.

Example 2

On the basis of the embodiment 1, as shown in fig. 1 and fig. 6 to 8, the heat insulation system comprises a first L-shaped supporting plate 201, a bellows 202, a rotating motor 203, a third rotating shaft 204, a third heat insulation plate 205, a fourth heat insulation plate 206 and a fifth heat insulation plate 207; a first L-shaped supporting plate 201 is welded on the upper side of the left part and the lower side of the right part of the spliced library body 2 respectively; one bellows 202 is welded on the upper parts of the two first L-shaped supporting plates 201 respectively; both bellows 202 are connected with a thermal insulation system; a rotating motor 203 is fixedly connected to the front parts of the two bellows 202 respectively; a third rotating shaft 204 is rotatably connected to the inside of each of the two bellows 202; the output shafts of the two rotating motors 203 are fixedly connected with a third rotating shaft 204 respectively; a third heat insulation plate 205 is fixedly connected to each of the two third rotating shafts 204; a fifth heat insulation plate 207 is fixedly connected to the upper surfaces of the inner parts of the two bellows 202 respectively; a fourth thermal insulation plate 206 is fixedly connected to the inner lower surfaces of the two bellows 202.

As shown in fig. 9-12, the dehumidification system comprises a support frame 301, a first guide pipe 302, a second L-shaped support plate 303, a fan 304, a water molecule removing mechanism 305 and a second guide pipe 306; the upper side of the rear part of the assembled warehouse body 2 is connected with a supporting frame 301 through bolts; the support frame 301 is fixedly connected with a first guide pipe 302; the first guide pipe 302 is arranged on the left bellows 202 in a penetrating way; a second L-shaped supporting plate 303 is fixedly connected to the lower side of the rear part of the spliced warehouse body 2; a fan 304 is fixedly connected to the second L-shaped supporting plate 303; the air inlet of the fan 304 is fixedly connected with a first guide pipe 302; a water molecule removing mechanism 305 is fixedly connected to the lower side of the rear part of the assembled warehouse body 2, and the water molecule removing mechanism 305 is positioned on the right of the fan 304; the air outlet of the fan 304 is fixedly connected with a water molecule removing mechanism 305; the right part of the water molecule removing mechanism 305 is connected with a second flow guiding pipe 306; the second guide pipe 306 is arranged on the right bellows 202 in a penetrating way.

The water molecule removing mechanism 305 includes a connection base 3051, a fixed cover 3052, a rotating cover 3053, a punching shell 3054, a first fixed plate 3055, a second servo motor 3056, a second flat gear 3057, a first dust collection net 3058, a second dust collection net 3059, a second fixed plate 30510, a connection frame 3051, a carrying case 30512, a carrying door 3053 and a third flat gear 30510; a connecting seat 3051 is fixedly connected to the lower side of the rear part of the assembled warehouse body 2, and the connecting seat 3051 is positioned on the right of the fan 304; a fixed cover 3052 is fixedly connected to the connecting seat 3051; the upper part of the fixed cover 3052 is rotatably connected with a rotary cover 3053; the right part of the fixed cover 3052 is fixedly connected with an expanding shell 3054; the inner side of the right part of the fixed cover 3052 is fixedly connected with a second dust collection net 3059; the left part of the fixed cover 3052 is fixedly connected with a first dust collection net 3058; the first dust collection net 3058 is connected with an air outlet of the fan 304; two symmetrical second fixing plates 30510 are fixedly connected to the fixing cover 3052; two second fixing plates 30510 are fixedly connected with a connecting frame 30511 respectively; a bearing box 30512 is welded between the two connecting frames 30511; the bearing box 30512 is rotatably connected with a bearing door 30513; a third flat gear 30510 is fixedly connected to the right connecting frame 30511; a first fixing plate 3055 is welded on the rear side of the right part of the assembled warehouse body 2; a second servo motor 3056 is fixedly connected to the first fixing plate 3055; the output shaft of the second servo motor 3056 is fixedly connected with a second flat gear 3057; the output shaft of the second servo motor 3056 is rotationally connected with the fixed cover 3052; the second flat gear 3057 meshes with the third flat gear 30514.

Two flow contraction rings are welded inside the fixed cover 3052 and are used for intensively flowing air flow into the bearing box 30512.

The inner side of the carrying case 30512 is provided with a plurality of small holes for improving water molecule absorption.

When the data transmitted back by the four humidity sensors 8 indicate that the humidity of the cold storage is too high, the two rotating motors 203 are controlled to operate at the moment, the two rotating motors 203 respectively drive one third rotating shaft 204 to rotate ninety degrees, the two third rotating shafts 204 respectively drive one third heat insulation plate 205 to rotate ninety degrees, therefore, the third heat insulation plate 205 leaves the fourth heat insulation plate 206 and the fifth heat insulation plate 207, air in the cold storage can circulate from the two bellows 202, then a fan 304 is started to operate, the fan 304 pumps air in the cold storage, the air in the cold storage flows into a first guide pipe 302 from the left bellows 202, then flows into the fan 304 from the first guide pipe 302 to finally be converted into a water molecule removing mechanism 305, at the moment, the air in the cold storage is firstly passed through a first dust collection net 3058, the first dust collection net 3058 carries out filtration adsorption on granular sundries in the cold storage, the surface of vegetables and fruits is prevented from being adsorbed on, rotten is caused, then the air can flow to the middle part of a motor 3053 under the action of a flow ring of a fixed cover 2, then the motor 3053 is started to operate, and a second flat-shaped motor 3053 is controlled to rotate, and then a second flat-shaped carrier 3053 is connected with a second bearing box 3053, namely a second bearing box 3053 is arranged in a bearing box 3053, and a bearing box 3053 is connected to a second bearing box 3053, and a second bearing box 3053 is connected to a second bearing box 3053, and a top is realized, and a bearing box 3053 is connected with a second bearing box 3053, and a 12, and a bearing box 3053 is simultaneously, and a bearing device is connected with a top box 3053 and a 12, and a bearing box 3053 is a 12 is rotated; the air continuously flows through the space in the middle of the bearing box 30512, and the water absorption substances continuously absorb water molecules in the air, so that the humidity in the refrigerator is regulated, meanwhile, the air is filtered again through the second dust collection net 3059, the air is cleaner, the fresh-keeping and refrigerating quality is improved, the dehumidified air reaches the right bellows 202 through the second guide pipe 306, the height of the right bellows 202 is lower than that of the left bellows 202, the air with water molecules removed continuously fills the whole refrigerator, and meanwhile, a gas flow channel is formed, so that the air with more water molecules flows to the water molecule removing mechanism 305 more quickly, and the humidity regulation is realized.

Example 3

On the basis of the embodiment 2, as shown in fig. 1 and 3-5, an isolation system is also included; the front side inside the assembled warehouse body 2 is connected with an isolation system; the isolation system comprises a first rotating shaft 101, a first servo motor 102, a sliding block 107, a connector 108 and a folding mechanism; the upper side of the inside of the assembled warehouse body 2 is provided with a chute, and three sliding blocks 107 are connected in a sliding way; the front side of the left surface inside the spliced warehouse body 2 is rotationally connected with a first rotating shaft 101; the left part of the upper surface of the assembled warehouse body 2 is fixedly connected with a first servo motor 102; the output shaft of the first servo motor 102 is fixedly connected with a first rotating shaft 101; the first rotating shaft 101 is connected with a folding mechanism; the two sliding blocks 107 on the right are connected with a folding mechanism; two connectors 108 are sleeved between the two folding mechanisms; the left folding mechanism is connected to the leftmost slider 107.

The right folding mechanism and the left folding mechanism are arranged in a mirror image mode; the folding mechanism comprises a first heat insulation plate 103, a second heat insulation plate 104, a second rotating shaft 105 and a first flat gear 106; a first heat insulation plate 103 is fixedly connected to the first rotating shaft 101; the left slider 107 is rotatably connected with a second rotating shaft 105; the middle slide block 107 is rotatably connected with a second rotating shaft 105; the right slider 107 is rotatably connected with a second rotating shaft 105; the right part of the first heat insulation plate 103 is rotatably connected with a second heat insulation plate 104; the right part of the second heat insulation plate 104 is rotationally connected with a left second rotating shaft 105; the upper part of the second rotating shaft 105 at the left side is fixedly connected with a first flat gear 106; the outer surfaces of two adjacent second rotating shafts 105 at the left are sleeved with two connectors 108; the upper part of the middle second rotating shaft 105 is fixedly connected with a first flat gear 106; the left first flat gear 106 is meshed with the right first flat gear 106; the right first heat insulation plate 103 is rotatably connected with the rightmost second rotating shaft 105; the first right thermal insulation plate 103 is rotatably connected to the second right thermal insulation plate 104.

In the above embodiment, the operation of controlling gas isolation of the region to be transferred in the splice library 2 is an isolation system; after the staff places the goods and wait to change the district after, in order to avoid the freezer to open the direct convection of cold air and outside air when moving, the goods is before putting into the freezer storage area, close first two protection door 5, control first servo motor 102 operation afterwards, first servo motor 102 drives first pivot 101 and rotates, first pivot 101 then drives left folding mechanism and moves, first pivot 101 drives first heat insulating plate 103 and rotates, corresponding second heat insulating plate 104 then starts pulling the slider 107 of leftmost along with the rotation form of first heat insulating plate 103 and moves this moment, therefore left first heat insulating plate 103 and second heat insulating plate 104 are finally folded together, simultaneously right folding mechanism relies on two first flat gears 106 to transmit, two connectors 108 are responsible for the stability of two folding mechanisms, simultaneously right two sliders 107 drive whole right folding mechanism and realize folding, folding mode is unanimous with left this mode, just so can avoid the cold air loss in the freezer to realize intelligent energy-conservation effectively simultaneously.

Example 4

On the basis of the embodiment 3, as shown in fig. 1 and 13-14, an exhaust system is also included; the right upper side of the rear part of the spliced warehouse body 2 is connected with an exhaust system; the exhaust system comprises a fixed box 401, a rear cover 402, an exhaust pipe 403, a third dust collection net 404, an impeller 405, an electric telescopic piece 406, a third fixed plate 407 and a sixth heat insulation plate 408; two fixed boxes 401 are welded on the right upper side of the rear part of the assembled warehouse body 2; a rear cover 402 is fixedly connected to the rear parts of the two fixing boxes 401 respectively; two rear covers 402 are provided with an exhaust pipe 403 in a penetrating way; two third dust collection nets 404 are fixedly connected to the rear sides of the inside of the two fixed boxes 401 respectively; two impellers 405 are fixedly connected in the two fixed boxes 401 respectively, and the four impellers 405 are positioned in front of the corresponding third dust collection net 404; two electric telescopic members 406 are fixedly connected to the right upper side of the rear part of the assembled warehouse body 2, and two fixing boxes 401 are positioned between the two electric telescopic members 406; the telescopic parts of the two electric telescopic parts 406 are fixedly connected with a third fixed plate 407; four sixth heat insulation plates 408 are fixedly connected to the bottom of the third fixing plate 407.

The air exchange is needed to be intermittently realized in the refrigerator, the fresh smell in the refrigerator is kept, the air exchange time is usually selected to be six points earlier, the temperature difference between the external air and the refrigerator is the smallest, two electric telescopic parts 406 are controlled to operate, the telescopic parts of the two electric telescopic parts 406 drive the third fixing plates 407 to move upwards, the third fixing plates 407 drive the four sixth heat insulation plates 408 to move upwards, at the moment, the refrigerator and the outside realize the air flow channel, then four impellers 405 are controlled to operate, the four impellers 405 are used for pumping out the air in the refrigerator outwards, the air exchange is realized, the air in the refrigerator is filtered through the third dust collection net 404 and then is discharged through the exhaust pipe 403, and then the two electric telescopic parts 406 are controlled to operate and return, so that the four sixth heat insulation plates 408 block the two fixing boxes 401, and excessive loss of the cold air is avoided.

It will be appreciated by persons skilled in the art that the above embodiments are not intended to limit the invention in any way, and that all technical solutions obtained by means of equivalent substitutions or equivalent transformations fall within the scope of the invention.

Claims (5)

1. An intelligent refrigeration house with humidity regulation comprises an assembled house body (2), a sliding rail (3), an electric control moving block (4), a protection door (5), refrigeration equipment (7) and a humidity sensor (8); the front part of the upper surface of the spliced warehouse body (2) is connected with a sliding rail (3); the slide rail (3) is connected with two electric control moving blocks (4) in a sliding way; two electric control moving blocks (4) are fixedly connected with a protection door (5) respectively; the rear part of the assembled warehouse body (2) is connected with refrigeration equipment (7); the left side surface and the right side surface inside the spliced warehouse body (2) are respectively connected with two humidity sensors (8); the method is characterized in that: the system also comprises a heat preservation system and a dehumidification system; the upper side of the left part and the lower side of the right part of the spliced warehouse body (2) are respectively connected with a heat preservation system for preventing cold air from flowing to the outside; the right side of the rear part of the assembled house body (2) is connected with a dehumidifying system for removing superfluous water molecules in the refrigerator; the two heat preservation systems are connected with the dehumidification system;

the heat preservation system comprises a first L-shaped supporting plate (201), an air box (202), a rotating motor (203), a third rotating shaft (204), a third heat insulation plate (205), a fourth heat insulation plate (206) and a fifth heat insulation plate (207); the upper side of the left part and the lower side of the right part of the assembled warehouse body (2) are fixedly connected with a first L-shaped supporting plate (201) respectively; the upper parts of the two first L-shaped supporting plates (201) are fixedly connected with an air box (202) respectively; the two bellows (202) are connected with a heat preservation system; the front parts of the two bellows (202) are fixedly connected with a rotating motor (203) respectively; a third rotating shaft (204) is rotatably connected in each of the two bellows (202); the output shafts of the two rotating motors (203) are fixedly connected with a third rotating shaft (204) respectively; a third heat insulation plate (205) is fixedly connected on each of the two third rotating shafts (204); the upper surfaces of the interiors of the two bellows (202) are fixedly connected with a fifth heat insulation plate (207) respectively; the lower surfaces of the interiors of the two bellows (202) are fixedly connected with a fourth heat insulation plate (206) respectively;

the dehumidification system comprises a support frame (301), a first guide pipe (302), a second L-shaped support plate (303), a fan (304), a water molecule removing mechanism (305) and a second guide pipe (306); the upper side of the rear part of the assembled warehouse body (2) is fixedly connected with a supporting frame (301); the support frame (301) is fixedly connected with a first guide pipe (302); the first guide pipe (302) is arranged on the left bellows (202) in a penetrating way; a second L-shaped supporting plate (303) is fixedly connected to the lower side of the rear part of the spliced warehouse body (2); a fan (304) is fixedly connected on the second L-shaped supporting plate (303); an air inlet of the fan (304) is fixedly connected with a first guide pipe (302); a water molecule removing mechanism (305) is fixedly connected to the lower side of the rear part of the assembled warehouse body (2), and the water molecule removing mechanism (305) is positioned on the right of the fan (304); an air outlet of the fan (304) is fixedly connected with a water molecule removing mechanism (305); the right part of the water molecule removing mechanism (305) is connected with a second flow guiding pipe (306); the second guide pipe (306) is arranged on the right bellows (202) in a penetrating way;

the water molecule removing mechanism (305) comprises a connecting seat (3051), a fixed cover (3052), a rotary cover (3053), a punching shell (3054), a first fixed plate (3055), a second servo motor (3056), a second flat gear (3057), a first dust collection net (3058), a second dust collection net (3059), a second fixed plate (30510), a connecting frame (30511), a bearing box (30512), a bearing door (30513) and a third flat gear (3059); a connecting seat (3051) is fixedly connected to the lower side of the rear part of the assembled warehouse body (2), and the connecting seat (3051) is positioned on the right of the fan (304); a fixed cover (3052) is fixedly connected on the connecting seat (3051); the upper part of the fixed cover (3052) is rotatably connected with a rotary cover (3053); the right part of the fixed cover (3052) is fixedly connected with an expanding shell (3054); the inner side of the right part of the fixed cover (3052) is fixedly connected with a second dust collection net (3059); the left part of the fixed cover (3052) is fixedly connected with a first dust collection net (3058); the first dust collection net (3058) is connected with an air outlet of the fan (304); two symmetrical second fixing plates (30510) are fixedly connected to the fixing cover (3052); two second fixing plates (30510) are fixedly connected with a connecting frame (30511) respectively; a bearing box (30512) is fixedly connected between the two connecting frames (30511); the bearing box (30512) is rotatably connected with a bearing door (30513); a third flat gear (30510) is fixedly connected on the right connecting frame (30511); a first fixing plate (3055) is fixedly connected to the rear side of the right part of the assembled warehouse body (2); a second servo motor (3056) is fixedly connected to the first fixing plate (3055); the output shaft of the second servo motor (3056) is fixedly connected with a second flat gear (3057); an output shaft of the second servo motor (3056) is rotationally connected with the fixed cover (3052); the second flat gear (3057) is meshed with the third flat gear (30514);

the inner side of the bearing box (30512) is provided with a plurality of small holes for improving the absorption of water molecules;

the bearing box (30512) is internally provided with a water absorbing substance.

2. The intelligent refrigerator with humidity adjustment according to claim 1, wherein: the fixed cover (3052) is fixedly connected with two flow shrinkage rings inside and used for intensively flowing the air flow into the bearing box (30512).

3. The intelligent refrigerator with humidity adjustment according to claim 1, wherein: also comprises an identifier (6); a recognizer (6) with fingerprint and face recognition is arranged at the front part of each of the two protection doors (5).

4. An intelligent refrigerator with humidity control according to claim 3, wherein: the system also comprises an isolation system; the front side of the interior of the spliced warehouse body (2) is connected with an isolation system; the isolation system comprises a first rotating shaft (101), a first servo motor (102), a sliding block (107), a connector (108) and a folding mechanism; a sliding groove is formed in the upper side of the inside of the assembly warehouse body (2), and three sliding blocks (107) are connected in a sliding manner in the sliding groove; the front side of the left surface inside the assembled warehouse body (2) is rotationally connected with a first rotating shaft (101); the left part of the upper surface of the assembly warehouse body (2) is fixedly connected with a first servo motor (102); an output shaft of the first servo motor (102) is fixedly connected with a first rotating shaft (101); the first rotating shaft (101) is connected with a folding mechanism; the two sliding blocks (107) on the right are connected with a folding mechanism; two connectors (108) are sleeved between the two folding mechanisms; the left folding mechanism is connected with the leftmost sliding block (107);

the right folding mechanism and the left folding mechanism are arranged in a mirror image mode; the folding mechanism comprises a first heat insulation plate (103), a second heat insulation plate (104), a second rotating shaft (105) and a first flat gear (106); a first heat insulation plate (103) is fixedly connected to the first rotating shaft (101); the left sliding block (107) is rotatably connected with a second rotating shaft (105); the middle sliding block (107) is rotatably connected with a second rotating shaft (105); the right sliding block (107) is rotatably connected with a second rotating shaft (105); the right part of the first heat insulation plate (103) is rotatably connected with a second heat insulation plate (104); the right part of the second heat insulation plate (104) is rotationally connected with a left second rotating shaft (105); the upper part of the left second rotating shaft (105) is fixedly connected with a first flat gear (106); the outer surfaces of two adjacent second rotating shafts (105) at the left are sleeved with two connectors (108); the upper part of the middle second rotating shaft (105) is fixedly connected with a first flat gear (106); the left first flat gear (106) is meshed with the right first flat gear (106); the right first heat insulation plate (103) is rotationally connected with the rightmost second rotating shaft (105); the first right heat insulating plate (103) is rotatably connected with the second right heat insulating plate (104).

5. The intelligent refrigerator with humidity adjustment according to claim 4, wherein: the air exhaust system is also included; the right upper side of the rear part of the spliced warehouse body (2) is connected with an exhaust system; the exhaust system comprises a fixed box (401), a rear cover (402), an exhaust pipe (403), a third dust collection net (404), an impeller (405), an electric telescopic piece (406), a third fixed plate (407) and a sixth heat insulation plate (408); two fixed boxes (401) are fixedly connected on the right upper side of the rear part of the assembled warehouse body (2); the rear parts of the two fixed boxes (401) are fixedly connected with a rear cover (402) respectively; the two rear covers (402) are provided with an exhaust pipe (403) in a penetrating way; two third dust collection nets (404) are fixedly connected to the rear sides of the interiors of the two fixed boxes (401) respectively; two impellers (405) are fixedly connected in the two fixed boxes (401) respectively, and the four impellers (405) are positioned in front of the corresponding third dust collection net (404); two electric telescopic pieces (406) are fixedly connected to the right upper side of the rear part of the assembled warehouse body (2), and two fixing boxes (401) are positioned between the two electric telescopic pieces (406); the telescopic parts of the two electric telescopic parts (406) are fixedly connected with a third fixed plate (407); four sixth heat insulation plates (408) are fixedly connected to the bottom of the third fixing plate (407).