KR101040030B1 - Drying, precooling and thawing device - Google Patents

Abstract

PURPOSE: A drying, pre-cooling, and thawing apparatus is provided to remarkably reduce the installation space, and to stably perform drying, pre-cooling and thawing processes with one apparatus. CONSTITUTION: A drying, pre-cooling, and thawing apparatus comprises the following: a movable type warehouse(300) including plural containers with openings laminated in the inside, and a door; an indoor equipment unit(200) located in the inside of the movable type warehouse for inhaling internal air from the movable type warehouse for controlling the temperature; an outdoor equipment unit connected to the indoor equipment unit; a differential pressure structure(600) sealing openings of loading pallets for laminating the containers; a compressor supplying hot gas to the indoor equipment unit; and an evaporator heat exchanging a first coolant and a second coolant supplied from first and second coolant condensing coils.

Description

Drying, precooling and thawing devices {DRYING, PRECOOLING AND THAWING DEVICE}

The present invention relates to a drying, precooling and thawing apparatus, and more particularly, to a drying, precooling and thawing apparatus of a product using a differential pressure.

In general, dried vegetables such as onions, sweet potatoes, potatoes, garlic, and yams are used to remove moisture contained in the skin, root, and stem at the time of harvest, and the primary processing of dried agricultural products such as cabbage, radish, pumpkin, and eggplant. It refers to lowering the water content of the by-products, such as by-products, after dry processing such as forest products, and the first processing of leafy vegetables such as lettuce and Chinese cabbage, at a predetermined time. Pre-chilled vegetables, such as lettuce, broccoli, spinach, lettuce, sesame leaf, leek, leek, strawberry, bokbunja, mulberry, cucumber, pumpkin, tomato and vegetables, plums, grapes, peaches, etc. It refers to the cooling process to enter as soon as possible as conditions that can suppress the physiological phenomena such as action, ethylene biosynthesis, transpiration. Defrosting refers to the operation of raising the temperature of the frozen product such as aquatic products, livestock products, processed foods, etc. before the secondary processing and packaging.

The conventional drying method is a simple drying method for circulating hot air by using a blower fan in a facility using electric heat or fuel combustion as a heat source, or circulating effective air below a certain temperature in parallel with a heat pump method using a cooler; There is a freeze-vacuum drying method combining accessory equipment such as vacuum chamber and cold chamber. However, in the simple drying method, the differential pressure structure is not realized, and the hot wind directly touches the hot wind after the loading, thereby causing excessive drying and discoloration, change of shape, and deformation of the product. Due to the irregular drying, it is difficult to expect even quality, and also requires a lot of energy and ventilation amount, so that the work was difficult. In addition, the freeze-vacuum drying method combining the vacuum chamber and the accessory equipment is limited to the high value-added items due to the difficulty of work as well as excessive rejection of many initial facilities and expensive initial investment costs. There was a limit to enemy use. Therefore, the by-products generated after the operation of leafy vegetables contain a lot of water but also contain a lot of water, which is not suitable for compost or livestock feeding. Therefore, many problems such as odors, wastewater, and pests are continuously raised. It is still causing social problems because it remains at the level of wastewater treatment through crushing after crushing.

Conventional precooling methods include a differential pressure precooling method and a vacuum precooling method, and the differential pressure precooling method uses a refrigerant directly and is limited to a fixed building, and has a hassle of covering a differential pressure sheet manually and walking by a worker. . In addition, due to the large amount of cooling load required for pre-cooling, the size of the freezer must be excessive, and even if the solenoid valve is closed by the temperature controller at the lower limit of the set temperature, It is operated at high temperature and the effective air of low temperature below the set temperature is strongly circulated to bring low temperature damage to the product. To prevent low temperature damage, the discharge temperature should be kept at a constant temperature, but it is very difficult to control it. there was. Furthermore, although it is called differential pressure precooling, the opening is formed for the purpose of conveying the pallet to load the product, and a considerable amount of effective air is circulated to reduce the precooling efficiency, and the complete differential pressure cannot be realized. The situation is becoming. Although the vacuum precooling method has the advantage of fast preheating time, it requires a considerable period of time to expand the facility depending on the import and does not lead to the continuous technical support, as well as the burden on the initial investment cost and the preheating purpose or product of the product. There was a problem that access is difficult because the conditions of use are not correct.

The thawing method is operated by setting the temperature of the effective air circulated under the conditions described in the conventional drying method higher or exposed to the air, or by thawing by contacting water at an appropriate temperature according to the product. It was limited in such a simple way.

In general, products that require rapid drying, pre-cooling, and thawing vary somewhat depending on the item, but the process must be performed to maintain quality, improve shelf life, and achieve the desired work. Conventional facilities have limitations in carrying out the drying, precooling and thawing processes with simple plant and method limitations. In addition, the treatment of by-products generated during the pre-treatment process, such as packaging of vegetables, has long been an environmental problem as described above. As a method for treating this, waste water treatment after crushing juice has been attempted. In addition, there is still a problem in the odor treatment method that occurs when the solution or decay of the waste, as well as the waste water treatment facilities and costs.

Therefore, it is possible to move freely as well as to freely select space, and to perform various operations such as quick differential pressure drying, precooling, and thawing as one device, and to achieve low cost facility and maintenance costs. Development is required.

Therefore, the problem to be solved by the present invention is movable, can significantly reduce the constraints of the installation space, can significantly reduce the installation cost, and can be stably operated with a low maintenance cost as one device It is to provide a drying, precooling and thawing apparatus.

Drying, pre-cooling and thawing apparatus according to an exemplary embodiment of the present invention is a plurality of stacking containers having openings formed in the interior space is stacked, a mobile storage including a door and the mobile storage is disposed inside the mobile storage The internal air is sucked through the suction unit, and the temperature is adjusted, and then supplied again into the mobile reservoir through the discharge unit, so that the negative pressure is generated on the suction side and the positive pressure is generated on the discharge side, so that the temperature-controlled air is connected to the suction unit. The indoor unit allows passage between the air gaps of the products loaded in the plurality of loading containers in which the openings are formed by the pressure difference generated between the discharge parts, and can be connected to the outdoor unit and move integrally with the mobile reservoir. And an outdoor unit installed outside the movable storage.

The movable storage compartment seals at least a part of an opening layer for insulating heat from the outside, openings of the loading pallets on which the plurality of loading containers are stacked, and a differential pressure structure for supporting the loading containers stacked in the mobile storage container; It may further include a differential pressure protection plate for supporting the differential pressure relief and forming a suction passage so that only the air passing through the loading container is guided to the indoor unit unit suction side.

On the other hand, the entrance door of the mobile reservoir may be an overhead door, the open upper surface of the loading container located at the top of the stacked stacking containers in the mobile storage can be sealed by the differential pressure sheet.

In addition, one end of the differential pressure sheet is connected to the overhead door of the mobile storage, and as the overhead door is elevated, one end of the differential pressure sheet is lifted to open and close the upper surface of the loading container located at the top. You can. The movable reservoir may further be provided with a pipe roller for supporting the differential pressure sheet which is interlocked and elevated as the overhead door is raised.

In one embodiment, the outdoor unit is provided with a primary refrigerant to discharge the hot gas of high temperature and high pressure to provide a portion to the indoor unit, a compressor for receiving and condensing the remaining amount except the portion of the hot gas discharged from the compressor Condensing from the first primary refrigerant condensing coil, the second primary refrigerant condensing coil for receiving and condensing the hot gas recovered according to the circulation of the primary refrigerant in the indoor unit, and the first primary refrigerant condensing coil and the second primary refrigerant condensing coil And an evaporator for exchanging heat exchanged primary and secondary refrigerants. The indoor unit is provided with secondary refrigerant from the outdoor unit to cool the inside of the mobile reservoir, and receives a primary gas in a hot gas state from the compressor of the outdoor unit and removes the drop of the compressor from the compressor of the outdoor unit. And a reheat coil provided with a primary gas in a hot gas state to compensate for the temperature inside the mobile reservoir.

In one embodiment, the outdoor unit is a storage tank for storing a secondary refrigerant for supplying to the cooling coil of the indoor unit, a recovery tank for receiving and storing the secondary refrigerant recovered from the cooling coil of the indoor unit unit and the shaft It may further include a secondary refrigerant tank disposed between the cold tank and the recovery tank, the secondary coolant tank comprising a separator separating the secondary refrigerant stored in the storage tank and the secondary refrigerant stored in the recovery tank. In addition, the outdoor unit may pump the secondary refrigerant stored in the recovery tank to provide the evaporator to the secondary refrigerant circulation pump for circulating the secondary refrigerant and the secondary refrigerant stored in the storage cooling tank to the indoor unit. It may further include a secondary refrigerant supply pump for supplying. The drying, precooling and thawing apparatus may operate the secondary refrigerant supply pump when the temperature inside the mobile reservoir becomes higher than a predetermined temperature, and the upper limit of the temperature of the secondary refrigerant stored in the storage tank is preset. The controller may operate the secondary refrigerant circulation pump when the temperature is higher than the temperature, and stop the operation of the secondary refrigerant circulation pump when the temperature of the secondary refrigerant stored in the storage cooling tank is lower than a preset lower limit temperature. It may include.

In an embodiment, the outdoor unit recovers and stores the primary refrigerant condensed in the first primary refrigerant condensation coil and the primary refrigerant condensed in the second primary refrigerant condensation coil, and provides the stored primary refrigerant to the evaporator. Refrigerant recovery vessel, receiving the primary refrigerant from the evaporator to separate the primary refrigerant in the liquid state that has not evaporated, and receives the liquid separator for providing the evaporated primary refrigerant to the compressor and the high temperature and high pressure hot gas discharged from the compressor After separating the oil may further include an oil separator for providing a hot gas from which the oil is separated to the indoor unit.

The reheat coil may be divided into at least two reheat coil headers so that at least two stages of control may be provided to receive the primary refrigerant in the hot gas state in at least two paths from the compressor of the outdoor unit.

In an embodiment, the indoor unit may define an external shape of the indoor unit and accommodate the cooling coil and the reheat coil in a space formed therein, and between an inner casing, an outer casing, and the inner casing and the outer casing. An insulator disposed therein, an inlet formed to allow the air in the mobile reservoir to be sucked into the inside by the pressure difference by the blower fan, and a discharge portion formed so that the temperature controlled by the blower fan can be discharged to the mobile reservoir It may further comprise a casing comprising.

According to the present invention, by the above configuration, the effective air temperature controlled between the pores of the product contained in the loading container not only circulates quickly and evenly, but also does not require a separate artificial work that can cover and walk the differential pressure sheet. It allows you to dry, precool, or thaw high-quality products quickly and in a minimum amount of space with minimal work and energy, resulting in significant savings in labor and maintenance costs.

In addition, the indoor unit is disposed in the mobile storage and the outdoor unit is installed outside the mobile storage so that it can be moved together with the mobile storage. There is an advantage to this.

In addition, drying, pre-cooling or thawing processes may be possible with one device in one place regardless of the overall process, location, quantity, working method, outdoor air, etc. It not only improves and saves energy, but also significantly increases the exchange interval of the facility.

In addition, by applying hot gas of the secondary refrigerant and heat pump method, stable temperature control and humidity control may be possible, and in parallel with the heat pump method, initial facility cost and operation cost may be reduced due to the reduction of the required power and energy. Can be.

1 is a perspective view of a drying, pre-cooling and thawing apparatus according to an embodiment of the present invention
Figure 2 is an exploded view of a mobile reservoir according to an embodiment of the present invention
3 is a cross-sectional plan view of a mobile reservoir.
4 is a side sectional view of a mobile reservoir;
5 is a front sectional view of a mobile reservoir.
6 is a configuration diagram of an outdoor unit and an indoor unit according to an embodiment of the present invention;
7 is a front view illustrating the outside of the outdoor unit of FIG. 6.
8 is a view showing a compressor, an oil separator, a primary refrigerant recovery container, a suction gas liquid separator, a secondary refrigerant tank, and the like disposed inside the outdoor unit.
9 is a view showing a first primary refrigerant condensation coil and a second primary refrigerant condensation coil disposed inside the outdoor unit.
10 is a front view showing the outside of the indoor unit of FIG.
FIG. 11 is an exploded view for explaining the configuration of the outdoor unit of FIG. 6.

As the inventive concept allows for various changes and numerous embodiments, particular embodiments will be illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to the specific disclosed form, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms "comprise" or "having" are intended to indicate that there is a feature, number, step, action, component, part, or combination thereof described in the specification, and that one or more other features It should be understood that it does not exclude in advance the possibility of the presence or addition of numbers, steps, actions, components, parts or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art.

Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art, and shall not be construed in ideal or excessively formal meanings unless expressly defined in this application. Do not.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

1 is a perspective view of a drying, precooling and thawing apparatus according to an embodiment of the present invention, Figure 2 is an exploded view of a mobile reservoir according to an embodiment of the present invention, Figure 3 is a plan sectional view of the mobile reservoir, Figure 4 Is a side cross-sectional view of the mobile reservoir, and FIG. 5 is a front sectional view of the mobile reservoir.

1 to 5, the drying, pre-cooling and thawing apparatus according to an embodiment of the present invention may include a mobile storage 300, the indoor unit 200 and the outdoor unit 100.

The mobile reservoir 300 has a plurality of side portions 311a, 311c, 311d and 311g connected to each other and an upper surface portion 311b for sealing an upper portion of the side portions 311a, 311c, 311d and 311g. ) And a bottom portion 311i sealing the lower portions of the side surfaces 311a, 311c, 311d, and 311g. The movable storage 300 is, for example, it is preferable that a container is used as a box-shaped structure formed in a hexahedral shape with a space formed therein. In addition, an entrance door 311f may be formed at one of the side parts 311a of the side parts 311a, 311c, 311d, and 311g. The door 311f formed in the mobile storage 300 may be, for example, an overhead door. In addition, an emergency door 311e may be further formed on one of the side parts 311d of the side parts in which the door 311f is not formed.

In addition, a heat insulation layer 331 may be further formed inside the mobile reservoir 300 to insulate the outside of the mobile reservoir 300, and the insulation layer 331 may be, for example, a urethane that is formed inside the mobile reservoir. The layer may be formed of a galvanized steel sheet or an iron plate to cover the urethane layer, and in particular, the side parts 311a, 311c, 311d, 311g and the upper surface 311b may be finished with a galvanized steel sheet. Preferably, the bottom portion 311 i is preferably finished with an iron plate. Here, the urethane layer may be omitted in the bottom portion 311i. In the internal space of the mobile storage 300, a plurality of stacking containers 500 having openings (not shown) formed on the pallet 400 are stacked, and a product (shown in the stacking containers having the openings formed therein) is illustrated. Is not loaded). That is, after loading the product inside the stacking containers 500 from the outside of the mobile storage 300, the stacking containers 500 are stacked on the pallet 400 to stack the stacking containers 500. In the forklift using the forklift through the door 311f of the mobile storage 300 is moved to the interior of the mobile storage 300 is stored. Here, the loading containers 500 are formed in the form of a box having an open top, and a plurality of openings (shown in the side parts and the bottom part so that the temperature controlled air passes evenly by the pressure difference between the pores of the loaded product). May not be formed).

In addition, at least a portion of the opening 400a of the stacking pallets 400 in which the plurality of stacking containers 500 are stacked is sealed in the movable storage 300, and in the movable storage 300. Differential pressure structure 600 for supporting the stacked stacking containers 500 may be further installed.

Here, the differential pressure structure 600 includes a pair of lower members 600a, a pair of vertical members 600b, and a horizontal member 600c. The pair of lower members 600a includes an opening unit and an indoor unit of the loading pallets 400 located on the indoor unit unit 200 side of the loading pallets 400 in which a plurality of loading containers 500 are stacked. The openings of the loading pallets 400 located on the opposite side of the unit 200 may be sealed. The pair of vertical members 600b may be connected to and fixed to the pair of lower members 600a to support side portions of the stacked stacking containers 500. The horizontal member 600c may support an upper end of one side of the stacking containers 500 in which both end portions are connected and fixed to the upper ends of the pair of vertical members 600b.

The pressure differential structure 600 as described above not only supports the loading containers 500 stacked on the pallets, but also includes a opening tool formed on the indoor unit unit side of the loading pallets 400 located on the indoor unit 200 side. Sealing the openings formed on the opposite side of the indoor unit unit of the loading pallets 400 located on the opposite side of the indoor unit 200, through the openings formed on the indoor unit unit side and the indoor unit unit opposite side of the loading pallets 400 Do not allow air to circulate.

In addition, the suction passage 710 which supports the differential pressure relief team 600 in the mobile reservoir 300 and allows only the air passing through the loading vessels 500 to be guided and sucked to the indoor unit unit suction part GR2. The differential pressure protection plate 700 may be further installed.

Here, the differential pressure protection plate 700 may include a side plate 700a and an upper plate 700b. The side plate 700a of the differential pressure protection plate 700 is in close contact with the vertical member 600b of the differential pressure structure 600 located on the opposite side of the indoor unit 200, and the side portion 311a on which the door 311f is formed. ) Is installed to be in close contact with the side portion (311g) of the mobile storage 300 facing the vertical support (600b) and at the same time the air passing through the loading vessels 500 is located on the opposite side of the indoor unit 200 It prevents from escaping to the side part 311d side of the reservoir 300. The top plate 700b is connected to the upper end of the side plate 700a, one side is in close contact with the horizontal member 600c of the differential pressure structure 600, and the other side is facing the side portion 311a formed with the door 311f. It is installed to be in close contact with the side portion (311g) of the mobile storage 300 to support the horizontal member 600c and at the same time the air passing through the stacking container 500 to escape to the upper side of the stacking container 500 prevent.

The differential pressure protection plate 700 forms a suction passage 710 so that the air passing through the stacking vessels 500 is located on the side portion 311d of the mobile storage unit 300 opposite to the indoor unit 200 and the stacking vessels ( By being guided to the suction unit GR2 side of the indoor unit 200 without exiting to the upper side of the 500, the air circulation efficiency by the differential pressure in the mobile reservoir 300 is improved, thereby greatly improving drying or precooling or thawing efficiency. To improve.

In addition, the drying, pre-cooling and thawing apparatus according to an embodiment of the present invention covers the upper surface of the stacking container 500 located at the top of the stacking containers 500 stacked in the mobile storage 300 to seal the pressure differential sheet 800 may be further included.

The differential pressure sheet 800 as described above passes through the pores of the products contained in the stacking containers 500 by covering and sealing an open upper portion of the stacking containers 500 positioned at the top of the stacked stacking containers 500. By preventing air from escaping to the outside of the open upper surface of the loading vessels 500 located at the top, the air circulation efficiency due to the differential pressure is improved, thereby greatly improving drying or precooling or thawing efficiency.

Here, the differential pressure sheet 800 may cover the open top of the loading container located at the uppermost end by the operator by hand or pulled out from the loading containers 500. Preferably, however, one end of the differential pressure sheet 800 is fixed to the horizontal member 600c of the differential pressure relief member 600 and the other side is connected to the door 311f, that is, the overhead door, so that the overhead door is elevated. When lifted along the door frame 311h for guiding the lift, in conjunction with the overhead door, the lift is automatically lifted to cover the opened upper portions of the loading containers 500 located at the top and to seal or roll the open.

When the differential pressure sheet 800 is elevated in conjunction with the overhead door, a pipe roller 810 may be further installed in the movable storage 300. The pipe roller 810 is installed to be rotatable on the upper surface of the movable reservoir 300 so that the overhead door is raised, as shown in b of FIG. 4, the differential pressure sheet 800 is loaded with containers 500. The differential pressure sheet 800 supports the differential pressure sheet 800 so that the differential pressure sheet 800 does not sag toward the stacking containers 500 when it is rolled from

The indoor unit 200 is disposed in the mobile reservoir 300 to suck the air in the mobile reservoir 300 through the suction unit GR2, and then, after adjusting the temperature, the mobile reservoir 300 through the discharge unit GR1. ) Is supplied back to the inside, so that the negative pressure is generated at the suction part GR2 and the positive pressure is generated at the discharge part GR1, so that the temperature-controlled air is supplied to the suction part GR2. And the pressure difference generated between the discharge portion GR1, that is, the pressure difference between the gaps of the product contained in the plurality of loading containers 500 with openings formed by the differential pressure.

The outdoor unit 100 is connected to the indoor unit 200 and is installed outside the mobile reservoir so as to be integrated with the mobile reservoir 300.

As described above, the drying, pre-cooling and thawing apparatus according to the embodiment of the present invention is provided on the opposite side of the opening of the pallets 400 formed on the indoor unit 200 by the differential pressure structure 700 and the indoor unit 200. The openings of the formed pallets 400 are sealed to prevent air from being sucked into the openings of the pallets 400 so that the air exits the loading containers 500 by the differential pressure protection plate 700. The product is contained by using a forklift by allowing the whole amount to be sucked to the suction part GR2 side without exiting to the side portion 311d side of the mobile storage 300 located on the upper side of the loading containers 500 or opposite to the indoor unit 200. After placing the loading containers 500 in the mobile storage 300, closing the door 311f, and then operating the blower fan UF of the indoor unit 200, the discharge portion of the indoor unit 200 Positive pressure on the GR1) side The negative pressure is generated on the suction part GR2 side to form a complete differential pressure.

In addition, the differential pressure sheet 800 is connected to the overhead door to open or seal the upper portion of the top loading containers 500 automatically loaded as the overhead door is elevated, the loading containers There is an advantage that does not need to secure a separate input personnel to open or close the top of the 500.

Thus, not only does the temperature-controlled effective air circulate quickly and evenly between the pores of the product contained in the stacking containers 500, but also does not need to perform an additional artificial work to cover and walk the differential pressure sheet 800, so that it can be quickly In this way, high quality products can be dried, precooled or thawed in a minimal space with minimal work and energy.

In addition, in the drying, pre-cooling and thawing apparatus according to an embodiment of the present invention, the indoor unit 200 is disposed in the mobile storage 300 and the outdoor unit 100 is movable so that it can be moved together with the mobile storage 300. Since it is installed outside the storage 300, only the electric drawing is possible, and thus there is an advantage that it can be easily moved without using any installation place.

6 is a configuration diagram of an outdoor unit and an indoor unit according to an embodiment of the present invention.

Referring to FIG. 6, the outdoor unit 100 and the indoor unit 200 according to an embodiment of the present invention are provided as separate devices. The outdoor unit 100 and the indoor unit 200 are connected by primary refrigerant pipes hp3 and mp4 and secondary refrigerant pipes bp5 and bp6, and the primary refrigerant pipes hp3 and mp4. Secondary refrigerant pipes bp5 and bp6 distribute the primary refrigerant and the secondary refrigerant, respectively.

The outdoor unit 100 and the indoor unit 100 may further include a controller (DC) for controlling various components provided. The controller DC may be, for example, a digital controller.

FIG. 7 is a front view illustrating the exterior of the outdoor unit of FIG. 6, and FIGS. 8 and 9 are exploded views for explaining the configuration of the outdoor unit of FIG. 6. FIG. 8 is a view illustrating a compressor, an oil separator, a primary refrigerant recovery container, a suction gas liquid separator, a secondary refrigerant tank, and the like disposed in an outdoor unit, and FIG. 9 is a diagram of a first primary refrigerant condensing coil and an agent disposed in an outdoor unit. 2 is a view showing a primary refrigerant condensation coil.

6 to 9, the outdoor unit 100 includes a compressor 111, an oil separator 112, a first primary refrigerant condensing coil 113, and a second primary refrigerant to form a circulation structure of the primary refrigerant. Condensation coil 114, the primary refrigerant recovery container 115, the plate evaporator 116 and the suction gas liquid separator 117.

The compressor 111 receives primary refrigerant to produce hot gas at high temperature and high pressure, and the produced hot gas is discharged through a pipe hp1.

The oil separator 112 receives the discharged hot gas at a high temperature and high pressure, separates the oil, and discharges the oil to a pipe (hp2). The hot gas passing through the pipe (hp2) reaches the three-way solenoid valve (SV1), the three-way solenoid valve (SV1) is the indoor unit unit 200 through the pipe (hp3) by a predetermined amount of hot gas To pass.

The circulation of the primary refrigerant delivered to the indoor unit 200 will be described later.

The first primary refrigerant condensation coil 113 receives a residual amount of hot gas that is not transferred from the three-way solenoid valve SV1 to the indoor unit 200 through a pipe hp3, through a pipe hp4. At this time, both sides of the first primary refrigerant condensation coil 113 is provided with a condensation coil header 113a.

The first primary refrigerant condensation coil 113 is heat-exchanged with the outside air by the adjacent blowing fan (CF1), and thus the hot gas is condensed into a liquid of medium temperature and high pressure.

The second primary refrigerant condensation coil 114 is a reheating / defrosting hot gas condensing coil, and the reheating hot gas delivered through the pipe (mp4) in accordance with the circulation of the primary refrigerant in the indoor unit 200 to be described later and Receive hot gas for recycling. The reheat / defrost hot gas is incompletely condensed, partly liquefied and partly uncondensed. At this time, both sides of the second primary refrigerant condensation coil 114 is provided with a condensation coil header (114a).

The second primary refrigerant condensation coil 114 is heat-exchanged with the outside air by the blowing fan (CF1) disposed adjacent to, so that the incompletely condensed hot gas is safely condensed into a liquid of medium temperature and high pressure.

As such, the outdoor unit 100 may condense the first primary refrigerant condensing coil 113 for condensing the hot gas discharged from the compressor 111 and the second primary refrigerant condensation for condensing the hot gas for reheating and defrosting. Since the coil 114 is separated and included, it is possible to prevent an abnormal phenomenon of the system due to excessive consumption of electrical energy of the conventional electric heat transfer method and unstable reheating and non-condensable gas of the heat pump method.

The primary refrigerant recovery container 115 recovers the liquid refrigerant condensed in the first primary refrigerant condensation coil 113 through a pipe (mp5), and the liquid condensed in the second primary refrigerant condensation coil 114. The refrigerant in the state is recovered through the pipe mp6.

The primary refrigerant in the liquid state recovered from the primary refrigerant recovery container 115 passes through the pipeline lp2 according to the opening and closing operation of the solenoid valve SV5 through the pipeline lp1, and throttles in the expansion valve EXV1. .

The plate type evaporator 116 is provided with a primary refrigerant via pipes lp1 and lp2, the solenoid valve SV5 and the expansion valve EXV1, and the secondary refrigerant introduced in the circulation of the secondary refrigerant, which will be described later. Heat exchange. The heat exchanged primary refrigerant cools the secondary refrigerant and evaporates itself by absorbing heat.

By using the plate evaporator 116, the disadvantage that the compressor has a surplus evaporation capacity at the time of refrigerant suction can be utilized to cool the secondary refrigerant in the plate evaporator 116, compared to the conventional compressor for secondary refrigerant cooling The operation time of 111 can be shortened.

The suction gas liquid separator 117 receives the evaporated primary refrigerant through a pipe lp3 to separate the primary refrigerant in the liquid state that is not evaporated. The primary refrigerant passing through the suction gas liquid separator 117 is again sucked into the compressor 111 through the pipe lp4.

The outdoor unit 100 includes a secondary refrigerant tank 118, a secondary refrigerant circulation pump 119, and a secondary refrigerant supply pump 120 to form a secondary refrigerant circulation structure.

The secondary refrigerant tank 118 may be, for example, a refrigeration brine tank. The secondary refrigerant tank 118 includes a cold storage tank BTa, a recovery tank BTb, and a separator plate BTc.

The storage tank BTa stores the secondary refrigerant for supplying the indoor unit 200.

The recovery tank BTb stores the secondary refrigerant used and recovered by the indoor unit 200.

The separator BTc is disposed between the storage tank BTa and the recovery tank BTb to insulate the secondary refrigerant stored in the storage tank BTa and the secondary refrigerant stored in the recovery tank BTb from each other. .

The secondary refrigerant circulation pump 119 pumps the secondary refrigerant stored in the recovery tank BTb to provide the plate type evaporator 116 through the pipes bp1 and bp2 to circulate the secondary refrigerant. The secondary refrigerant circulation pump 119 may operate according to an operation signal of the controller DC.

The secondary refrigerant supply pump 120 pumps the secondary refrigerant stored in the storage cooling tank BTa and supplies the secondary refrigerant to the indoor unit 200 through pipes bp4 and bp5. Specifically, the secondary refrigerant supply pump 120 is cooled by heat exchange with the primary refrigerant in the plate evaporator 116 to supply the secondary refrigerant stored in the storage tank BTa to the indoor unit 200. .

The secondary refrigerant supply pump 120 may operate according to an operation signal of the controller DC. In one embodiment, the indoor temperature sensor (T2) for detecting the indoor temperature of the mobile storage in which the indoor unit 200 is installed detects the indoor temperature of the storage and the detected temperature is input to the controller (DC). . The controller DC operates the secondary refrigerant supply pump 120 when the indoor temperature detected by the indoor temperature sensor T2 is higher than a preset temperature. Accordingly, the secondary refrigerant stored in the storage tank BTa may be introduced into the indoor unit 200 through the pipes bp4 and bp5.

A heat storage secondary coolant temperature sensor T4 may be inserted into the heat storage refrigeration tank BTa, and the heat storage secondary coolant temperature sensor T4 detects a temperature of the secondary refrigerant stored in the heat storage cooling tank BTa. A recovery secondary coolant temperature sensor T5 is inserted into the recovery tank BTb, and the recovery secondary coolant temperature sensor T5 detects a temperature of the secondary refrigerant stored in the recovery tank BTb.

When the predetermined temperature upper limit is detected by the secondary cooling temperature sensor T4, the controller DC outputs a signal to the secondary refrigerant circulation pump 119 and the secondary refrigerant circulation pump 119 operates. By the operation of the secondary refrigerant circulation pump 119, the secondary refrigerant stored in the recovery tank (BTb) is moved to the plate evaporator 116 through the pipes (bp1, bp2) and the plate evaporator 116 After cooling by heat exchange with the primary refrigerant in the pipe (bp3) is moved to the storage cold tank (BTa). This process may be automatically repeated to operate when the temperature of the secondary refrigerant sensed by the secondary cold storage temperature sensor T4 of the cold storage tank BTa reaches a preset temperature upper limit and stops when the preset temperature lower limit is reached.

Accordingly, when the secondary refrigerant supply pump 120 is stopped, the primary refrigerant existing in the cooling coil 211 of the indoor unit 200, which will be described later, is also stopped, thereby improving safety, and increasing the room temperature when the pump is down. The problem of lowering below the set temperature can be prevented. In addition, since the supply temperature of the secondary refrigerant can be maintained in an appropriate range, a problem of temperature deviation that may occur when cooling by using the primary refrigerant can be prevented, and it occurs in the cooling coil 211 of the indoor unit 200. It is possible to easily adjust the optimum temperature of the secondary refrigerant in consideration of the dew point temperature in order to easily defrost the defrosting.

The outdoor unit 100 may further include a casing C1. The casing C1 defines an external shape of the outdoor unit 100, and the components described above in the space formed therein, that is, the compressor 111, the oil separator 112, and the first primary refrigerant condensation. Coil 113, the second primary refrigerant condensation coil 114, the primary refrigerant recovery container 115, the plate evaporator 116, the suction gas liquid separator 117, the secondary refrigerant tank 118, the A secondary refrigerant circulation pump 119 and the secondary refrigerant supply pump 120 are accommodated.

FIG. 10 is a front view illustrating the outside of the indoor unit of FIG. 6, and FIG. 11 is an exploded view for explaining the configuration of the outdoor unit of FIG. 6.

1, 4, 10, and 11, the indoor unit 200 includes a cooling coil 211 and a reheat coil 212.

The cooling coil 211 is a low-temperature secondary refrigerant supplied by the secondary refrigerant supply pump 120 from the storage cooling tank BTa of the outdoor unit 100, and a three-way solenoid valve of the outdoor unit 100 ( The primary refrigerant in the state of hot gas (reheat / defrosting hot gas) supplied in a predetermined amount by SV1 is provided. The secondary coil and the hot gas are supplied to the cooling coil 211 by being separated into a cooling coil header 211a and a defrosting coil header 211b so that the secondary refrigerant and the hot gas are not mixed with each other. The cooling coil 211 may be divided into a cooling coil and a defrosting coil to separate and distribute the secondary refrigerant and the hot gas.

The secondary coolant having a low temperature is supplied to the cooling coil 211 of the indoor unit 200 through the coil header 211a for cooling, and is circulated by a blower fan UF of the indoor unit 200. Cool the room air at (300). The secondary coolant having cooled indoor air and having a raised temperature is recovered to the recovery tank BTb of the outdoor unit 100 through a pipe bp6.

As described above, the operation is performed when the temperature of the secondary refrigerant stored in the cold storage tank BTa sensed by the cold storage secondary coolant temperature sensor T4 of the cold storage tank BTa reaches a preset temperature upper limit, and the preset temperature is set. When the lower limit is reached, it can be automatically repeated to stop.

On the other hand, a part of the hot gas (reheat / defrosting hot gas) supplied through the pipe hp3 is utilized for defrosting. The defrosting hot gas may be guided to the cooling coil 211 through the defrosting coil header 211b, and may remove the drop formed in the cooling coil 211 by the heat of the induced hot gas. At this time, the opening and closing of the solenoid valve SV2 may be adjusted according to a signal of a predetermined defrost timer.

An incomplete condensation state in which part of the hot gas is condensed and part is not condensed due to heat exchange that occurs when removing the drop formed in the cooling coil 211 by the hot gas induced in the defrost coil header 211b. It becomes The incompletely condensed hot gas passes through a pipe mp4 past the check valve CHK1 and is supplied to the condensation coil header 114a of the outdoor unit 100.

According to the defrosting method as described above, it is possible to prevent the risk of high heat or electric leakage, which is a disadvantage of conventional defrosting by electric heater electrothermal.

The reheat coil 212 compensates for or raises the room temperature inside the mobile reservoir, which is cooled by heat exchange. The reheat coil 212 may operate in parallel with the operation of cooling the secondary refrigerant of the secondary refrigerant tank 118.

The reheat coil 212 receives a portion of the hot gas (reheat / defrost hot gas) supplied from the outdoor unit 100 for reheating. In this case, the reheat coil 212 is separated into two first reheat coil headers 212a and a second reheat coil header 212b in one embodiment, and reheat hot gas through pipes hp6 and hp7, respectively. Can be supplied.

In detail, the reheat coil 212 may be formed using the first reheat coil header 212a and the second reheat coil header 212b to ensure stability and to freely adjust the reheat load of the reheat coil 212. It can be separated into two paths to allow control of the steps.

A humidity sensor H1 is disposed in the mobile storage, and the humidity sensor H1 senses humidity and inputs it to the controller DC. The controller DC may control the opening and closing of the solenoid valves SV3 and SV4 to supply the reheating hot gas to the reheating coil 212 in two paths. That is, the reheating hot gas may branch into the first reheating coil header 212a and the second reheating coil header 212b as necessary or may form only one path to exchange heat.

Thereafter, part of the reheating hot gas is liquefied and part is incompletely condensed without condensation. The incompletely condensed hot gas passes through the check valves CHK2 and CHK3, passes through the pipe mp4, and moves to the condensation coil header 114a in the outdoor unit 100.

In the reheating method as described above, the cooling coil of the indoor unit 200 to artificially discharge a part of the absolute humidity, that is, the total amount of water contained in the air and the agricultural products in the mobile storage, to the outside of the mobile storage ( The dew point temperature of 211) can be derived.

According to the reheating method as described above, it is possible to prevent the risk of high heat or electric leakage, which is a disadvantage of reheating by the conventional electric heater electric heat. In addition, since the reheating device 212 for compensating or raising the indoor temperature inside the mobile storage heat exchanged and cooled using only a heat source of hot gas discharged from the compressor 111 without a separate heat source may be more efficient than the conventional method. have.

The indoor unit 200 may further include a casing C2 and a structure ST2. The casing defines an outer shape of the indoor unit 200 and is supported by the structure ST2 and accommodates the cooling coil 211 and the reheat coil 212 in a space formed therein.

In addition, the casing C2 of the indoor unit 200 has a suction part GR2 formed so that the air in the mobile storage 300 may be sucked into the inside by the pressure difference by the blower fan UF, and the blowing It includes a discharge portion (GR1) is formed so that the air temperature controlled by the fan (UF) can be discharged to the mobile reservoir (300). Here, the suction part GR2 and the discharge part GR1 may be formed in a grille shape, and a plurality of blower fans UF may be disposed in the vertical direction of the casing C2.

As described above, when the secondary refrigerant supply pump 120 stops, the primary refrigerant existing in the cooling coil 211 of the indoor unit 200 may also be stopped, thereby improving safety. In addition, since the supply temperature of the secondary refrigerant can be maintained in an appropriate range, a problem of temperature deviation that may occur when cooling by using the primary refrigerant can be prevented, and a problem that the indoor temperature falls below the set temperature due to the pump down occurs This can be prevented. In addition, it is possible to easily adjust the optimum temperature of the secondary refrigerant in consideration of the dew point temperature in order to be able to easily defrost the drip generated in the cooling coil 211 of the indoor unit 200.

In addition, according to the defrosting method as described above, it is possible to prevent the risk of high heat or electrical leakage, which is a disadvantage of conventional defrosting by electric heater electrothermal. In addition, in the conventional simple hot gas defrosting method, as described above, the compressor has a surplus evaporation capacity when the refrigerant is sucked in, so that the secondary refrigerant is cooled in the plate evaporator 116 and moved to the storage cooling tank BTa. It can be utilized to reduce the operating time of the compressor 111 for the secondary refrigerant cooling as compared to the conventional, it is possible to double the energy efficiently.

In addition, the outdoor unit 100 may condense the first primary refrigerant condensing coil 113 for condensing the hot gas discharged from the compressor 111 and the second primary refrigerant condensing coil for condensing the hot gas for reheating and defrosting. Since the 114 is separated and included, it is possible to prevent the excessive electric energy consumption of the conventional electric heat transfer method and the abnormal phenomenon of the system due to unstable reheating and non-condensable gas of the heat pump method.

In addition, according to the reheating method as described above, it is possible to prevent the risk of high heat or electric leakage, which is a disadvantage of the reheating by the conventional electric heater electric heat. In addition, since the reheating device 212 for compensating or raising the indoor temperature inside the mobile storage heat exchanged and cooled using only a heat source of hot gas discharged from the compressor 111 without a separate heat source may be more efficient than the conventional method. have.

In addition, the cooling coil 211 and the reheat coil 212 is configured separately, the first primary refrigerant condensation coil (exhaust gas condensation coil) 113 and the second primary refrigerant condensation coil (reheat / re-heat hot By separately configuring the gas condensation coil (114), in the conventional simple hot gas reheating method, it is possible to solve the problem that the indoor unit unit 200 is not recovered to the refrigerant recovery container due to the high pressure of the noncondensing gas. In addition, since the cooling temperature and the reheat temperature can be freely adjusted using the secondary refrigerant, cooling and reheating can be easily performed simultaneously.

While the present invention has been described in connection with what is presently considered to be practical and exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention. Therefore, the above description and the drawings below should be construed as illustrating the present invention, not limiting the technical spirit of the present invention.

(10) Drying, precooling and thawing apparatus
(100): outdoor unit (111): compressor
(112): oil separator (113): first primary refrigerant condensation coil
114: second primary refrigerant condensing coil (115): primary refrigerant recovery container
(116): plate evaporator (117): suction gas liquid separator
118: secondary refrigerant tank 119: secondary refrigerant circulation pump
120: secondary refrigerant supply pump 200: indoor unit
(211): cooling coil (212): reheat coil
300: Removable Storage 400: Pallets
(500): loading container (600): differential pressure rescue team
700: differential pressure protection plate 800: differential pressure sheet

Claims (8)

A plurality of stacking containers having openings formed in the inner space, the removable storage including an entrance door;
Is disposed inside the mobile reservoir to suck the air inside the mobile reservoir through the suction unit and adjust the temperature and supply it back to the mobile reservoir through the discharge unit, so that the negative pressure is generated on the suction side and the positive pressure is generated on the discharge side An indoor unit so as to allow the temperature controlled air to pass between the pores of the products loaded in the plurality of loading containers in which the openings are formed by the pressure difference generated between the suction part and the discharge part;
An outdoor unit connected to the indoor unit and installed outside the mobile reservoir so as to be integrated with the mobile reservoir; And
A differential pressure structure that seals at least a portion of openings of the stacking pallets in which the plurality of stacking containers are stacked, and supports the stacking containers stacked in the mobile storage,
The outdoor unit may include a compressor provided with primary refrigerant to discharge hot gas at a high temperature and high pressure to provide a portion to the indoor unit; A first primary refrigerant condensation coil configured to receive and condense the remaining amount of the hot gas discharged from the compressor except the portion; A second primary refrigerant condensing coil configured to receive and condense hot gas recovered by circulation of the primary refrigerant in the indoor unit; And an evaporator configured to heat exchange the primary refrigerant and the secondary refrigerant condensed from the first primary refrigerant condensation coil and the second primary refrigerant condensation coil.
The indoor unit may include: a cooling coil provided with secondary refrigerant from the outdoor unit to cool the inside of the mobile storage, and receiving a primary gas in a hot gas state from a compressor of the outdoor unit to improve the level of load; A reheat coil receiving the primary refrigerant in a hot gas state from the compressor of the outdoor unit to compensate for the temperature inside the mobile reservoir; And a plurality of air openings formed by the pressure difference by supplying the air inside the mobile reservoir through the suction unit and controlling the temperature by the cooling coil or the reheating coil, and then supplying the air back into the mobile reservoir through the discharge unit. Drying, pre-cooling and thawing apparatus comprising at least one blowing fan to pass through the loading container. The method of claim 1,
The removable storage,
Drying, pre-cooling and thawing apparatus further comprises a heat insulating layer for insulating the outside of the mobile storage. delete The method of claim 1,
Drying, pre-cooling and thawing apparatus further comprises a differential pressure protection plate for supporting the differential pressure rescue and forming a suction passage so that only the air passing through the loading container is guided to the indoor unit unit suction. The method of claim 1,
Drying, pre-cooling and thawing apparatus further comprises a differential pressure sheet for covering and sealing the open upper surface of the stacking container located at the top of the stacking containers stacked in the mobile storage. The method of claim 5, wherein
Drying, pre-cooling and thawing apparatus, characterized in that the entrance door of the mobile storage is an overhead door. The method according to claim 6,
The overhead door is connected to one end of the differential pressure sheet, and as the overhead door is elevated, the one end of the differential pressure sheet is lifted in conjunction with the overhead door to open and close an upper surface of the loading container located at the top. Drying, precooling and thawing apparatus. The method of claim 7, wherein
Drying, pre-cooling and thawing apparatus is characterized in that the movable reservoir is further provided with a pipe roller for supporting the differential pressure sheet which is elevated in conjunction with the overhead door is raised.

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