KR102565311B1 - Artificial intelligence-based environmental condition setting meat cold storage warehouse system - Google Patents

Abstract

The present invention relates to an AI-based environment condition setting meat refrigerated storage warehouse system that enables meat to be stored by automatically controlling the type and origin information of meat and appropriate temperature and humidity conditions.

Description

Artificial intelligence-based environmental condition setting meat cold storage warehouse system}

The present invention relates to an artificial intelligence-based environmental condition-setting meat freezer storage system, and more particularly, to an artificial intelligence-based environmental condition-setting meat storage system that enables meat to be stored by automatically controlling the type and origin information of meat and appropriate temperature and humidity conditions. It is about a refrigerated storage system.

In general, proper temperature control is essential to maintain the freshness of various foods or ingredients stored in a refrigeration system. That is, if the temperature of the refrigeration system is not properly controlled, unnecessary cooling is performed and the energy efficiency of the refrigeration system is lowered.

In addition, if the temperature control of the refrigeration system is not properly performed, frost can easily occur inside, which further deteriorates the cooling efficiency. Therefore, in the existing refrigeration system, the temperature inside the refrigerating chamber is frequently checked using a sensor, and the checked temperature By controlling the driving of the cooler according to, the inside of the refrigerating chamber is controlled to maintain an appropriate temperature at all times.

That is, the temperature control is performed in such a way that the operation of the cooler is stopped when the temperature inside the refrigerating compartment reaches a set temperature, and the cooler is driven again when the set temperature exceeds a certain range.

In the temperature control method in the conventional refrigeration system, the temperature of the refrigerating compartment continues to drop even though the cooler is not driven due to the latent heat remaining when the drive of the cooler is stopped, and as a result, the temperature is higher than the set temperature. There was a problem that serious damage to food or food materials being stored by descending could occur.

Korean Registered Patent No. 10-2069328

An object of the present invention is to ensure that meat can be stored by automatically controlling the optimum condition according to the type of land and country of origin, and the temperature and humidity to be stored.

The present invention is characterized by an artificial intelligence-based environmental condition setting meat refrigerated storage warehouse system that automatically controls meat type and origin information and appropriate temperature and humidity conditions to store meat.

In one embodiment, the meat freezer storage system includes: a meat storage unit for storing meat that has been cut or meat that has not been cut; And meat type, country of origin, temperature, humidity information and preset meat information stored in the meat storage unit are compared and calculated to be automatically controlled as conditions for storage, and the heat exchanger and air conditioner are automatically driven and controlled according to the meat information an automatic control unit formed on one side of the meat storage unit to provide storage status information and automatic control information to the management server unit in real time; And a manager server unit for receiving real-time storage information from the automatic control unit and transmitting it to the manager terminal, receiving new information from the manager terminal and inputting it to the automatic control unit; and a manager terminal for receiving real-time storage information from the manager server unit and transmitting new information to be input to the automatic control unit to the manager server unit, wherein the meat storage unit is configured to store meat that has been cut or meat before being cut. To control the inside of the warehouse booth, a heat exchanger formed on one side of the warehouse booth to control the temperature inside the warehouse booth, and to control the humidity inside the warehouse booth and to one side inside the warehouse booth so that deodorization can be controlled. A plurality of internal confirmation cameras are formed inside the warehouse booth to provide real-time storage status by providing the captured image to the automatic control unit, and the warehouse booth A temperature sensor formed on one side inside the warehouse booth to detect the temperature of the warehouse and provide the detected temperature information to the automatic control unit so that the heat exchanger can be driven It is characterized in that it includes a humidity sensor formed on the other side inside the warehouse booth so that the air conditioner can be driven by providing it to the side, and a plurality of meat loading frames formed inside the warehouse booth so that a plurality of stored meat can be seated. to be

In another embodiment, the meat cold storage warehouse system further includes a moving rail unit for placing meat products for storage and automatically moving to the meat loading frame side when information to be located on the automatic control unit side is input, , The moving rail part is a path along each path to the plate moving rail formed on the ground in the direction of the plurality of meat loading frames so that the moving plate can be seated and moved, and the central ground of the plate moving rail formed on the side of each meat loading frame A path detection sensor formed respectively so that the sensor can detect it, and a position detection sensor formed on the ground in each position of the meat loading frame to detect the movement of the moving plate moved by the path detection sensor to the meat loading frame side And, a moving plate on which meat products are seated, seated on a plate moving rail and formed to slide, and a front surface of the moving plate so that the moving plate can be moved by detecting one of a plurality of path detection sensors. A path sensor formed on the side, a plurality of driving rollers formed on the lower surface of the moving plate so that the moving plate can be slid and seated on the plate moving rail, and generating rotational power to be provided to one of the plurality of driving rollers. In order to provide a drive motor formed on one side of the lower surface of the seat and moving plate, one side is connected to the drive motor to provide rotational power of the drive motor to the drive roller side, and the other side is connected to any one drive roller among a plurality of drive rollers. In order to prevent the drive chain and the lifting plate that is raised and lowered from being damaged by contacting the moving plate during descent, a plurality of damage prevention pads formed on the upper surface of the moving plate, and formed on one side of the moving plate to support the lifting motor A motor fixing plate, an elevating motor seated on the motor fixing plate to raise and lower the elevating plate by rotating the elevating screw, and an elevating screw formed vertically connected to the elevating motor to rotate and raise and lower the elevating plate. The elevating plate and the elevating screw are combined with the elevating plate seated on the anti-damage pad at a certain interval from the moving plate so that the elevating plate can be raised and lowered in the vertical direction when the elevating screw rotates. Formed on one side of the elevating plate In order to prevent the screw member and the rising plate from being separated from the lifting screw, the separation preventing end formed at the upper end of the lifting screw and the lifting plate rising toward the separation prevention end are detected, and the detection information is sent to the lifting motor side. It is characterized in that it comprises a lifting and lowering sensor formed on the lower surface of the departure prevention end to provide.

As described above, the present invention allows meat to be stored under optimal conditions according to the type of land, origin information, and temperature and humidity to be stored, so that the meat does not deteriorate and is easily stored for a set period of time Provides the effect of making it easy do.

1 is a system schematic diagram of the artificial intelligence-based environmental condition setting meat refrigerated storage warehouse system of the present invention.
Figure 2 is a perspective view of a warehouse booth for the artificial intelligence-based environmental condition setting meat frozen storage warehouse system of the present invention.
FIG. 3 is an internal configuration diagram of FIG. 2 .
4 is a view showing an installed moving rail unit, which is another embodiment of the artificial intelligence-based environmental condition setting meat frozen storage warehouse system of the present invention.
5 is a detailed view of the movable rail unit of FIG. 4 .
6 is a view of an automatic loading unit, which is another embodiment of the artificial intelligence-based environmental condition setting meat cold storage warehouse system of the present invention.
FIG. 7 is a detailed view of FIG. 6 .
8 is a view of a scattering dust removal unit, which is another embodiment of the artificial intelligence-based environmental condition setting meat frozen storage warehouse system of the present invention.
9 is a detailed view of FIG. 8 .

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The detailed description of the present invention which follows refers to the accompanying drawings which illustrate, by way of illustration, specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable one skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different from each other but are not necessarily mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be implemented in another embodiment without departing from the spirit and scope of the invention in connection with one embodiment. Additionally, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the invention. Accordingly, the detailed description set forth below is not to be taken in a limiting sense, and the scope of the present invention, if properly described, is limited only by the appended claims, along with all equivalents as claimed by those claims. Like reference numbers in the drawings indicate the same or similar function throughout the various aspects.

Hereinafter, the present invention will be described in detail with reference to the drawings.

1 is a system schematic diagram of the artificial intelligence-based environmental condition setting meat frozen storage warehouse system 100 of the present invention, Figure 2 is a warehouse booth 111 for the present invention artificial intelligence-based environmental condition setting meat frozen storage warehouse system 100 ), and FIG. 3 is an internal configuration diagram of FIG. 2 .

As shown in the drawing, the warehouse system 100 is characterized in that meat can be stored by automatically controlling the type and country of origin information of meat and appropriate temperature and humidity conditions.

The warehouse system 100 is characterized in that it consists of a meat storage unit 110, an automatic control unit 150, a manager server unit 160, and a manager terminal 170.

The meat storage unit 110 is characterized in that for storing meat that has been cut or meat that has not been cut.

The meat storage unit 110 includes a warehouse booth 111, a heat exchanger 112, an air conditioner 113, an internal confirmation camera 114, a temperature sensor 115, a humidity sensor 116, a meat loading frame ( 117).

The warehouse booth 111 is formed to store meat that has been cut or meat that has not been cut, and is characterized in that the inside of the warehouse booth 111 is formed to be sealed.

The heat exchanger 112 is formed to control the temperature inside the warehouse booth 111, and the heat exchanger 112 is characterized in that it is formed on one side inside the warehouse booth 111.

The air conditioner 113 controls the humidity inside the warehouse booth 111 and is formed to control deodorization, and the air conditioner 113 is formed on one side inside the warehouse booth 111. to be

The internal confirmation camera 114 is formed so as to check the storage condition inside the warehouse booth 111 through an image, and provides the captured image to the automatic control unit 150 to provide a real-time storage state. The confirmation camera 114 is characterized in that a plurality is formed inside the warehouse booth 111.

The temperature sensor 115 is formed to sense the temperature of the warehouse booth 111 and provide the detected temperature information to the automatic control unit 150 so that the heat exchanger 112 can be driven. (115) is characterized in that it is formed on one side inside the warehouse booth (111).

The humidity sensor 116 is formed to detect the humidity of the warehouse booth 111 and provide the detected humidity information to the automatic control unit 150 so that the air conditioner 113 can be driven. The sensor 116 is characterized in that it is formed on the other side inside the warehouse booth 111.

The meat loading frame 117 is formed so that a plurality of meat to be stored can be seated, and the meat loading frame 117 is characterized in that a plurality of meat loading frames 117 are formed inside the warehouse booth 111.

The automatic control unit 150 compares and calculates the type, country of origin, temperature, and humidity information of the meat stored in the meat storage unit 110 with preset meat information, and automatically controls the storage condition according to the meat information. It is characterized in that it is formed on one side of the meat storage unit 110 so that automatic driving control of the 112 and the air conditioner 113 is performed, and storage state information and automatic control information are provided to the management server side in real time.

The manager server unit 160 receives real-time storage information from the automatic control unit 150 and transmits it to the manager terminal 170, receives new information from the manager terminal 170 and inputs it to the automatic control unit 150. to be characterized

The manager terminal 170 is characterized in that it receives real-time storage information from the manager server unit 160 and transmits new information to be input to the automatic control unit 150 to the manager server unit 160 side.

FIG. 4 is a view in which a moving rail unit 200, which is another embodiment of the artificial intelligence-based environmental condition setting meat storage warehouse system 100 of the present invention, is installed, and FIG. 5 is a view of the moving rail unit 200 for FIG. it is a detail

As shown in the drawing, the movable rail unit 200 is further included in the warehouse system 100, and the movable rail unit 200 seats meat products for storage, and the automatic control unit 150 side It is characterized in that it is for automatically moving to the side of the meat loading frame 117 when inputting information to be located in.

The moving rail unit 200 includes a plate moving rail 210, a path detection sensor 211, a position detection sensor 212, a seated moving plate 213, a path sensor 214, a driving roller 215, and a driving motor. (216), drive chain 217, damage prevention pad 218, motor fixing plate 219, lifting motor 220, lifting screw 221, lifting plate 222, screw member 223, breakaway It is characterized in that it includes a prevention end 224 and a lifting and lowering sensor 225.

The plate moving rail 210 is formed so that the moving plate 213 can be seated and moved, and the plate moving rail 210 is formed on the ground in the direction of the plurality of meat loading frames 117, respectively. do.

The path detection sensor 211 is formed on the central ground of the plate moving rail 210 formed on the side of each meat loading frame 117 so that the path sensor 214 can detect it according to each path.

The position detection sensor 212 is formed to detect the movement of the moving plate 213 moved by the path detection sensor 211 toward the corresponding meat loading frame 117, and the position detection sensor 212 It is characterized in that it is formed on the ground in each position of the meat loading frame 117.

The seating and movable plate 213 is characterized in that it is formed so that meat products are seated on it and seated on the plate movable rail 210 to slide.

The path sensor 214 is formed so that the moving plate 213 can be moved by sensing any one path sensor 211 among the plurality of path sensors 211, and the path sensor 214 It is characterized in that it is formed on the front side of the seating and moving plate 213.

The driving roller 215 is seated on the plate moving rail 210 and is formed so that the moving plate 213 can slide, and the driving roller 215 is formed in plurality on the lower surface of the moving plate 213 characterized by

The drive motor 216 is formed to generate rotational power to be provided to one of the plurality of drive rollers 215 to the side of the drive roller 215. It is characterized in that it is formed on one side.

The drive chain 217 is formed to provide rotational power of the drive motor 216 to the drive roller 215, one side of the drive chain 217 is connected to the drive motor 216, and the other side is plural. It is characterized in that it is connected to any one of the driving rollers 215 of the four driving rollers 215.

The anti-damage pad 218 is formed to prevent the elevating plate 222, which moves up and down, from being damaged by contacting the moving plate 213 when it descends. ) It is characterized in that a plurality is formed on the upper surface.

The motor fixing plate 219 is formed to support the elevating and descending motor 220, and the motor fixing plate 219 is formed on one side of the moving plate 213.

The elevating motor 220 is formed to elevate and lower the elevating plate 222 by rotating the elevating screw 221, and the elevating motor 220 is seated on the motor fixing plate 219. to be

The elevating screw 221 is formed to be rotated to elevate the elevating plate 222, and the elevating screw 221 is connected to the elevating motor 220 in a vertical direction.

The elevating plate 222 is characterized in that it is formed to be seated on the anti-breakage pad 218 at a predetermined interval from the moving plate 213.

The screw member 223 is formed so that the elevating plate 222 can be raised and lowered in the vertical direction when the elevating screw 221 is coupled to the elevating screw 221, and the screw member 223 is It is characterized in that it is formed on one side of the elevating plate 222.

The separation prevention end 224 is formed to prevent the lifting plate 222 from being separated from the elevation screw 221, and the separation prevention end 224 is the upper end of the elevation screw 221. It is characterized by being formed in.

The elevating sensor 225 is formed to sense the elevating plate 222 rising toward the separation prevention end 224 and provide detection information to the elevating motor 220. It is characterized in that the prevention end 224 is formed as a lower surface.

FIG. 6 is a view of an automatic loading unit 300, which is another embodiment of the artificial intelligence-based environmental condition setting meat frozen storage warehouse system 100 of the present invention, and FIG. 7 is a detailed view of FIG.

As shown in the drawing, the automatic loading unit 300 is further included in the warehouse system 100, and the automatic loading unit 300 moves up and down from the meat loading frame 117 where meat is to be stored. It is characterized in that meat products to be stored toward the meat loading frame 117 are automatically discharged and loaded.

The automatic loading unit 300 includes a loading transfer plate 310, a transfer roller 311, a transfer motor 312, a transfer chain 313, a transfer rail 314, a variable screw 315, and a screw fixing member 316 , screw transfer member 317, screw motor 318, stacking discharge plate 319, guide bar 320, bar fixing member 321, guide transfer member 322, variable bar 323, variable hinge ( 324), a load discharge roller 325, a load support 326, a support rotating motor 327, a load discharge cylinder 328, a height detection sensor 329, and a position detection member 330. .

The load transfer plate 310 supports the load discharge plate 319 that moves up and down and is formed to slide along the transfer rail 314, and the load transfer plate 310 is seated on the transfer rail 314. characterized by

The transfer roller 311 is formed so that the load transfer plate 310 can slide along the transfer rail 314, and the transfer roller 311 is characterized in that a plurality of transfer rollers 311 are formed below the load transfer plate 310 .

The transfer motor 312 is formed to generate rotational power for rotating the transfer roller 311, and the transfer motor 312 is formed on one side when the stack transfer plate 310 is formed.

The conveying chain 313 is formed to provide rotational power generated by the conveying motor 312 to one of the plurality of conveying rollers 311, and one side of the conveying chain 313 is It is connected to the transfer motor 312, and the other side is characterized in that it is formed to be connected to any one transfer roller 311 of the plurality of transfer rollers 311.

The transfer rail 314 is formed so that the transfer roller 311 is seated and slides, and the transfer rail 314 is formed on the ground.

The variable screw 315 is formed to move the screw transfer member 317, and the variable screw 315 is formed to rotate inside the load transfer plate 310.

The screw fixing member 316 is formed to support one side of the variable bar 323 that is changed by the screw conveying member 317 that is moved when the variable screw 315 rotates, and the screw fixing member 316 Is characterized in that the variable screw 315 is coupled to one side.

The screw conveying member 317 is formed to be movable when the variable screw 315 rotates, and the screw conveying member 317 is coupled to the other side of the variable screw 315.

The screw motor 318 is formed to rotate the variable screw 315, and the screw motor 318 is formed on one side outside the stacking transfer plate 310.

The loading and discharging plate 319 allows meat loads to be loaded, and is characterized in that it is connected to the loading transfer plate 310 by a variable bar 323 at a predetermined interval.

The guide bar 320 is formed so that the guide transfer member 322 can slide, and the guide bar 320 is fixedly formed into the loading/discharging plate 319.

The bar fixing member 321 is formed so that the other side of the variable bar 323 can be fixed on the guide bar 320, the bar fixing member 321 is fixed to one side of the guide bar 320 characterized by

The guide conveying member 322 is formed to slide along the guide bar 320, and the guide conveying member 322 is coupled to the other side of the guide bar 320.

The variable bars 323 are formed as a pair and are formed to cross each other, and one side of one of the pair is connected to the screw fixing member 316 and the other side is connected to the guide transfer member 322, and the other side is connected to the screw fixing member 316. One is characterized in that one side is connected to the bar fixing member 321 and the other side is formed to be rotatable by the variable hinge 324 so that it is connected to the screw feed member 317.

The variable hinge 324 is formed so that the pair of variable bars 323 can be mutually rotated, and the variable hinge 324 is formed at the center of the pair of variable bars 323. .

The load discharge roller 325 is formed so that meat products seated on the load discharge plate 319 are slidably discharged when the load discharge cylinder 328 is driven. It is characterized in that a plurality is formed on the upper surface.

The load support 326 is formed to support meat products discharged toward the meat loading frame 117, and the load support 326 is formed to rotate from the side of the load discharge plate toward the center.

The support rotation motor 327 is formed to generate rotational power for rotating the load support 326, and the support rotation motor 327 is formed on one side of the lower portion of the load discharge plate.

The load discharge cylinder 328 is formed to automatically discharge meat products seated on the load discharge roller 325 toward the meat loading frame 117, and the load discharge cylinder 328 is formed on one side of the upper portion of the load discharge plate characterized by being

The height sensor 329 is formed to detect the position sensing member 330 formed on one side of the inside of the meat loading frame 117, and the height sensor 329 is formed on one side of the load discharge plate. to be characterized

The position detecting member 330 is formed to be sensed by the height detecting sensor 329, and the position detecting member 330 is formed on one side inside the meat loading frame 117.

FIG. 8 is a view of a scattering dust removal unit 400, which is another embodiment of the artificial intelligence-based environmental condition setting meat frozen storage warehouse system 100 of the present invention, and FIG. 9 is a detailed view of FIG.

As shown in the drawing, the scattering dust removal unit 400 is a configuration further included in the warehouse system 100, and the scattering dust removal unit 400 is for removing dust inside the warehouse booth 111 to be characterized

The scattering dust removal unit 400 includes a dust removal box 410, a dust detection sensor 411, a suction port 412, a suction fan 413, a scattering blocking film 414, a moisture filter 415, and a spray liquid tank 416 ), high-pressure pump 417, spray injection pipe 418, spray nozzle 419, contaminated water guide plate 420, contaminated water storage box 421, water level detection sensor 422, contaminated water discharge door 423 ).

The dust removal bin 410 is characterized in that the sucked dust is formed on one side inside the warehouse booth 111.

The dust detection sensor 411 is formed to detect scattering dust inside the warehouse booth 111, and the dust detection sensor 411 is formed on one side outside the dust removal box 410.

The inlet 412 is formed so that the scattering dust sucked by the suction fan 413 flows into the dust removal box 410, and the inlet 412 is formed on one side of the upper part of the dust removal box 410. do.

The suction fan 413 is formed to suck the scattering dust inside the warehouse booth 111 toward the dust removal box 410, and the suction fan 413 is formed on the upper side of the other side of the dust removal box 410. do.

The scattering blocking film 414 is formed to block the movement of the spray liquid injected through the spray nozzle 419 to the suction fan 413, and the scattering blocking film 414 is formed in plurality on one side inside the dust removal box 410. characterized by the formation of

The moisture filter 415 is formed to block moisture moving through the scattering barrier film 414, and the moisture filter 415 is formed on one side of the suction fan 413.

The spray liquid tank 416 is formed to store the spray liquid to be moved at high pressure through the high-pressure pump 417, and the spray liquid tank 416 is formed above the dust removal box 410.

The high pressure pump 417 is formed to move the spray liquid inside the spray liquid tank 416 to the side of the spray liquid injection pipe 418 at a high pressure. characterized by the formation of

The spray liquid injection pipe 418 is formed to move the spray liquid moved at high pressure through the high pressure pump 417 to the spray nozzle 419 side, and the spray liquid injection pipe 418 has one side of the high pressure pump ( 417), and the other side is characterized in that it is formed as an inner upper surface of the dust removal box 410.

The injection nozzle 419 is formed to inject the injection liquid moved at high pressure into the dust removal box 410, and the injection nozzle 419 is formed in plurality on one side of the injection liquid injection pipe 418. do.

The contaminated water guide plate 420 is formed so that the injected liquid and the sucked dust can be mixed and moved toward the contaminated water storage box 421 when they fall. ) characterized in that it is formed inside.

The contaminated water storage box 421 is formed so that the contaminated water falling along the contaminated water guide plate 420 remains, and the contaminated water storage box 421 is formed on the inner bottom surface of the dust removal box 410. .

The water level sensor 422 is formed to detect the level of the contaminated water remaining in the contaminated water storage box 421, and the water level sensor 422 is formed on the inner side of the contaminated water storage box 421. to be

The contaminated water discharge door 423 is formed to discharge the contaminated water remaining in the contaminated water storage box 421. It is characterized in that it is formed to be openable to one side of the lower part of the dust removal box 410 to be discharged to the outside.

The above-described embodiments are for illustrative purposes, and those skilled in the art to which the above-described embodiments belong can easily transform into other specific forms without changing the technical spirit or essential features of the above-described embodiments. You will understand. Therefore, it should be understood that the above-described embodiments are illustrative in all respects and not restrictive. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as distributed may be implemented in a combined form.

The scope to be protected through this specification is indicated by the following claims rather than the detailed description above, and should be construed to include all changes or modifications derived from the meaning and scope of the claims and equivalent concepts thereof. .

100: warehouse system
110: meat storage unit 111: warehouse booth
112: heat exchanger 113: air conditioner
114: internal confirmation camera 115: temperature sensor
116: humidity sensor 117: meat loading frame
150: automatic control unit 160: manager server unit
170: manager terminal
200: moving rail part 210: plate moving rail
211: path detection sensor 212: position detection sensor
213: seated moving plate 214: path sensor
215: drive roller 216: drive motor
217: drive chain 218: anti-damage pad
219: motor fixing plate 220: lifting motor
221: elevating screw 222: elevating plate
223: screw member 224: departure prevention end
225: up and down sensor
300: automatic loading unit 310: loading transfer plate
311: transfer roller 312: transfer motor
313: transfer chain 314: transfer rail
315: variable screw 316: screw fixing member
317: screw transfer member 318: screw motor
319: loading and discharging plate 320: guide bar
321: bar fixing member 322: guide conveying member
323: variable bar 324: variable hinge
325: load discharge roller 326: load support
327: support rotating motor 328: load discharge cylinder
329: height detection sensor 330: position detection member
400: scattering dust removal unit 410: dust removal
411: dust sensor 412: inlet
413: suction fan 414: scattering barrier
415: moisture filter 416: injection liquid tank
417: high pressure pump 418: injection liquid injection pipe
419: injection nozzle 420: contaminated water guide plate
421: contaminated water storage box 422: water level detection sensor
423: polluted water discharge door

Claims (3)

In the artificial intelligence-based environmental condition setting meat storage warehouse system that automatically controls the type and origin information of meat and appropriate temperature and humidity conditions to store meat,
The meat frozen storage warehouse system,
A meat storage unit for storing meat that has been cut or meat that has not been cut; and
The type, country of origin, temperature, and humidity information of the meat stored in the meat storage unit is compared with the preset meat information to be automatically controlled as conditions for storage, and the heat exchanger and air conditioner are automatically controlled according to the meat information. and an automatic control unit formed on one side of the meat storage unit to provide storage status information and automatic control information to the management server unit in real time; and
A manager server unit for receiving real-time storage information from the automatic control unit and transmitting it to the manager terminal, receiving new information from the manager terminal and inputting it to the automatic control unit; and
It includes a manager terminal for receiving real-time storage information from the manager server and transmitting new information to be input to the automatic control unit to the manager server,

The meat storage unit,
A warehouse booth formed to be sealed inside to store meat that has been cut or meat before cutting;
A heat exchanger formed on one side inside the warehouse booth to control the temperature inside the warehouse booth;
An air conditioner formed on one side of the warehouse booth so that the humidity inside the warehouse booth can be controlled and deodorization can be controlled;
A plurality of internal confirmation cameras formed inside the warehouse booth so that the storage condition inside the warehouse booth can be checked through video and the captured video is provided to the automatic control unit to provide real-time storage status;
A temperature sensor formed on one side of the inside of the warehouse booth to detect the temperature of the warehouse booth and provide the detected temperature information to the automatic control unit so that the heat exchanger can be driven;
A humidity sensor formed on the other side inside the warehouse booth to sense the humidity of the warehouse booth and provide the detected humidity information to the automatic control unit so that the air conditioner can be driven;
Including a plurality of meat loading frames formed inside the warehouse booth so that a plurality of stored meat can be seated,

The meat frozen storage warehouse system,
Further comprising a moving rail unit for seating meat products for storage and automatically moving to the meat loading frame side when information to be located on the automatic control unit side is input,
The moving rail part,
Plate moving rails formed on the ground in the direction of a plurality of meat loading frames so that the moving plate can be seated and moved;
A path detection sensor formed on the central ground of the plate moving rail formed on the side of each meat loading frame so that the path sensor can detect each path along the path;
A position detection sensor formed on the ground at each position of the meat loading frame to detect the movement of the moving plate moved by the path detection sensor to the meat loading frame side;
A seating and moving plate on which meat products are seated and seated on the plate moving rail and formed to slide;
A path sensor formed on the front side of the moving plate so that the moving plate can be moved by detecting one of the plurality of path detecting sensors;
A plurality of driving rollers formed on the lower surface of the moving plate to be seated on the plate moving rail so that the moving plate can slide;
A drive motor formed on one side of the lower surface of the seating and moving plate to generate rotational power to be provided to one of the plurality of drive rollers;
A drive chain having one side connected to the drive motor and the other side connected to one of the plurality of drive rollers to provide rotational power of the drive motor to the drive roller;
A plurality of breakage prevention pads formed on the upper surface of the moving plate to prevent the ascending and descending plate from being damaged by contacting the moving plate during descent;
A motor fixing plate formed on one side of the moving plate to support the lifting and lowering motor;
An elevating motor seated on the motor fixing plate to raise and lower the elevating plate by rotating the elevating screw;
An elevating screw connected in the vertical direction by the elevating motor to raise and lower the elevating plate by rotation;
An elevating plate seated and formed on the anti-damage pad at a predetermined interval from the moving plate;
A screw member formed on one side of the elevating plate so that the elevating plate can be raised and lowered in a vertical direction when the elevating screw is rotated by combining the elevating screw;
A separation prevention end formed at the upper end of the elevating screw to prevent the rising elevating plate from being separated from the elevating screw;
An elevating sensor formed on the lower surface of the anti-elevating end to detect the elevating plate rising to the anti-elevating end and provide sensing information to the elevating motor,

The meat frozen storage warehouse system,
Further comprising an automatic loading unit for automatically discharging and loading meat products to be stored toward the meat loading frame by allowing the meat to be raised and lowered from the meat loading frame to be stored,
The automatic loading unit,
A loading transfer plate that supports the lifting and lowering loading and discharging plate and is seated on the transfer rail so as to slide along the transfer rail 314;
A plurality of transfer rollers formed under the stack transfer plate so that the stack transfer plate can be slid along the transfer rail;
A transfer motor formed on one side of the lower surface of the loading transfer plate to generate rotational power for rotating the transfer roller;
A transfer chain having one side connected to the transfer motor and the other side connected to any one of the plurality of transfer rollers to provide rotational power generated by the transfer motor to one of the plurality of transfer rollers;
A transfer rail formed on the ground so that the transfer roller is seated and slides;
A variable screw formed to be rotated inside the load transfer plate to move the screw transfer member;
A screw fixing member coupled to one side of the variable screw to support one side of the variable bar that is variable by the screw transfer member moved when the variable screw rotates;
A screw transfer member coupled to the other side of the variable screw so as to be moved when the variable screw rotates;
A screw motor formed on one side of the outside of the load transfer plate to rotate the variable screw;
A loading and discharging plate that allows meat loads to be loaded and is connected to the loading transfer plate by a variable bar at a predetermined interval;
A guide bar fixed to the inside of the stacking discharge plate so that the guide transfer member can slide;
A bar fixing member fixed to one side of the guide bar so that the other side of the variable bar can be fixed on the guide bar;
A guide transfer member coupled to the other side of the guide bar so as to slide along the guide bar;
It is formed as a pair and is formed to intersect with each other, and one side of the pair is connected to the screw fixing member, the other side is connected to the guide transfer member, and the other side is connected to the bar fixing member, and the other side is connected to the bar fixing member. A variable bar formed to be rotatable by a variable hinge so as to be connected to the screw conveying member;
A variable hinge formed at the center of the pair of variable bars so that the pair of variable bars can mutually rotate;
A plurality of load discharge rollers formed on the upper surface of the load discharge plate so that meat products seated on the load discharge plate are slide discharged when the load discharge cylinder is driven;
A load support formed to be rotated from the side of the load discharge plate to the center to support meat products discharged to the meat loading frame side;
A support rotation motor formed on one side of the lower portion of the load discharge plate to generate rotational power for rotating the load support;
A load discharge cylinder formed on one side of an upper portion of the load discharge plate to automatically discharge meat products seated on the load discharge roller toward the meat loading frame;
A height detection sensor formed on one side of the load discharge plate to detect a position sensing member formed on one side inside the meat loading frame;
An artificial intelligence-based environmental condition setting meat refrigerated storage warehouse system, characterized in that it includes a position sensing member formed on one side inside the meat loading frame to detect the height sensor. delete delete