JP6357889B2 - Refrigerated warehouse - Google Patents

Description

  The present invention relates to a refrigerated warehouse, and more particularly, to a refrigerated warehouse including a blower that forms an air curtain airflow.

  DESCRIPTION OF RELATED ART Conventionally, the refrigerator warehouse provided with the air blower which forms an air curtain airflow is known (for example, refer patent document 1).

  Patent Document 1 discloses a refrigerated warehouse provided with a partition air curtain unit (blower) including a blowout duct and a suction duct disposed so as to face the blowout duct. This refrigerated warehouse is configured such that the air cooled by the cooling device is blown out from the blowout duct as an air curtain and then sucked into the suction duct. Further, the air sucked from the suction duct is cooled again by the cooling device. A plurality of blowout ducts and suction ducts are provided, and a plurality of air curtains are formed. A plurality of regions (storage chambers) sandwiched between adjacent air curtains are formed. Moreover, the temperature of the area | region (storage chamber) pinched | interposed by the adjacent air curtain is adjusted by adjusting the temperature of the air curtain which blows off from a blowing duct. That is, one cooling device is provided for one storage chamber.

Japanese Utility Model Publication No. 2-116666

  However, in the refrigerated warehouse described in Patent Document 1, since one cooling device is provided for one storage room (article storage area), the configuration of the refrigerated warehouse is complicated accordingly. There is a problem.

  The present invention has been made to solve the above-described problems, and one object of the present invention is to cool a plurality of article storage regions while suppressing the complexity of the configuration. To provide a refrigerated warehouse.

In order to achieve the above object, a refrigerated warehouse according to one aspect of the present invention includes a first cooling device that supplies cold air to a first article storage area in which a first article is refrigerated and stored, and a second article that is refrigerated and stored. A second cooling device for supplying cold air to the second article storage area, a first air blowing unit for sucking the cold air from the first cooling device to form a first air curtain airflow, and the first air blowing unit. A third article that is disposed separately and can entrain a part of the first air curtain airflow, and is provided between the first article storage area and the second article storage area and the third article is refrigerated and stored. A first air blower that includes a second air blower that forms a second air curtain airflow that flows into the storage area, and a third air blower that sucks the cold air from the second cooling device to form a third air curtain airflow. And the third air blowing unit are spaced apart from each other, and the third air Together it is possible to involve some of Ten airflow, and a fourth blower for forming the fourth air curtain stream flowing into the third article storage area, comprising a second blower, a second blower The unit blows out the second air curtain airflow toward the lower side of the third article storage area, and sucks the blown second air curtain airflow on the upper side of the third article storage area, thereby The fourth air blower blows the fourth air curtain airflow toward the lower side of the third article storage area and the blown fourth air curtain airflow for the third time. By sucking in on the upper side of the article storage area, a circulation flow is formed in the third article storage area .

  In the refrigerated warehouse according to one aspect of the present invention, as described above, a part of the first air curtain airflow can be entrained and provided between the first article storage area and the second article storage area. The second air blower that forms the second air curtain airflow that flows into the third article storage area and the fourth air that can entrain a part of the third air curtain airflow and flows into the third article storage area It comprises so that the 4th ventilation part which forms a curtain airflow may be included. As a result, the second air curtain air flow that includes a part of the first air curtain air flow and the fourth air curtain that includes a part of the third air curtain air flow without providing a cooling device in the third article storage area. The third article storage area can be cooled by the airflow. As a result, unlike the case where a cooling device is provided in each of the first article storage area, the second article storage area, and the third article storage area, the plurality of article storage areas are cooled while suppressing the complexity of the configuration. be able to. In addition, the third article storage area can be cooled by the cold air mixed with the second air curtain airflow and the fourth air curtain airflow without providing a duct or the like in the third article storage area. Since it is not necessary to provide a duct or the like in the region, the plurality of article storage regions can be cooled while suppressing the complexity of the configuration.

In the refrigerated warehouse according to the above aspect, preferably, at least one of the second air curtain airflow formed by the second air blower and the fourth air curtain airflow formed by the fourth air blower, out of the air volume and the wind direction. By adjusting at least one, it is comprised so that the temperature of the 3rd article preservation | save area | region may be adjusted. If comprised in this way, at least one of a part of 1st air curtain airflow and a part of 3rd air curtain airflow can be wound easily.

In this case, preferably, the apparatus further includes a temperature measurement unit provided in the third article storage area, and based on the temperature measured by the temperature measurement unit, the second air curtain airflow and the fourth airflow formed by the second blower unit. The temperature of the third article storage area is adjusted by adjusting at least one of the air volume and the wind direction of at least one of the fourth air curtain airflows formed by the section. If comprised in this way, based on the temperature measured by the temperature measurement part, the temperature of a 3rd article preservation | save area | region can be easily hold | maintained at a fixed temperature.

In the refrigerated warehouse according to the above aspect, the first heat exchange is preferably provided in the third article storage area and performs heat exchange between the second air curtain airflow and the fourth air curtain airflow flowing into the third article storage area. The unit is further provided. If comprised in this way, since the temperature difference of the temperature of the 2nd air curtain airflow which flowed into the 3rd article preservation | save area | region and the temperature of the 4th air curtain airflow can be made small, it is the 3rd article. Variations in temperature within the storage area can be reduced (substantially uniform).

In the refrigerated warehouse according to the above aspect, the second air curtain airflow and the fourth air curtain airflow that are provided in the third article storage area and flow into the third article storage area are preferably cooled by the refrigerant, respectively . A heat exchange part is further provided . Here, when the refrigerant does not flow through the second heat exchange unit, the adjustable temperature in the third article storage area is a temperature range between the temperature of the first air curtain airflow and the temperature of the third air curtain airflow. Limited to. Therefore, as described above, by configuring the second air curtain airflow and the fourth air curtain airflow to be cooled by the refrigerant, respectively, the temperature of the first air curtain airflow and the temperature of the third air curtain airflow can be reduced. The temperature of the third article storage region can be adjusted beyond the temperature range in between.

  According to the present invention, as described above, it is possible to cool a plurality of article storage areas while suppressing the complexity of the configuration.

It is sectional drawing which showed the structure of the refrigerated warehouse by 1st Embodiment of this invention. It is a top view of the refrigerated warehouse in 1st Embodiment of this invention. It is a block diagram of the refrigerated warehouse in 1st Embodiment of this invention. It is sectional drawing which showed the structure of the refrigerator warehouse by 2nd Embodiment of this invention. It is the top view which showed the whole structure of the refrigerated warehouse in 2nd Embodiment of this invention. It is sectional drawing which showed the structure of the refrigerator warehouse by 3rd Embodiment of this invention.

  DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments embodying the present invention will be described below with reference to the drawings.

(First embodiment)
First, with reference to FIGS. 1-3, the refrigerated warehouse 100 by 1st Embodiment of this invention is demonstrated.

  As shown in FIG. 1, the refrigerated warehouse 100 according to the first embodiment is a refrigerated warehouse capable of storing a plurality of different types of articles (products) while the internal space 10 a is maintained at a predetermined temperature. . Specifically, the refrigerated warehouse 100 includes a refrigerated room 10 having an internal space 10a. Further, the internal space 10a includes a region 11 for storing an article 1 such as frozen food in a frozen state, and a region 12 for storing an article 2 such as another food in a refrigerator. The internal space 10a further includes a region 13 provided between the region 11 and the region 12 and in which the article 3 is stored in a refrigerator. Here, the region 11 is maintained at the temperature T1 in order to store the article 1 in a frozen state, and the region 12 is maintained at the temperature T2 in order to store the article 2 in a refrigerator. The region 13 is maintained at a temperature T3 in order to store the article 3 in a refrigerator. The temperature T1 (for example, −20 ° C.) is lower than the temperature T2 (for example, −15 ° C.), and the temperature T3 is a temperature between the temperature T1 and the temperature T2 (for example, −18 ° C.) (T1 < T3 <T2). The article 1, the article 2 and the article 3 are examples of the “first article”, the “second article” and the “third article” in the present invention, respectively. The region 11, the region 12, and the region 13 are examples of the “first article storage area”, the “second article storage area”, and the “third article storage area” of the present invention, respectively.

  Here, the internal space 10 a is not divided into the region 11, the region 12, and the region 13 by providing a partition for physically partitioning (partitioning) the inside of the refrigerator compartment 10. That is, the boundary region 10b between the region 11 and the region 13 and the boundary region 10c between the region 13 and the region 12 are not provided with a heat insulating partition or a structure such as a door that can be partially opened and closed. Therefore, an operator (loader (not shown)) who works in any one of the region 11, the region 12 and the region 13 passes through the boundary region 10b and the boundary region 10c in the X direction (X1 direction, X2 direction). It is configured to be possible.

  In addition, as described above, the region 11, the region 12, and the region 13 that are not partitioned from each other by using a physical partition in the refrigerator compartment 10 are refrigerated temperatures that are composed of different temperatures T1, T2, and T3, respectively. It is comprised so that it may be kept at. That is, the region 11, the region 12, and the region 13 are configured to be thermally divided into the temperature T1, the temperature T2, and the temperature T3 without using a partition wall.

  In order to thermally divide the inside of the refrigeration room 10, the refrigeration warehouse 100 sucks cold air from a cooling device 30 described later to form an air curtain air flow P1 (hereinafter referred to as air flow P1). 20 (blower part 20a) is provided. And the air blower 20 (blower part 20a) is comprised so that the airflow P1 may be blown down to the floor surface 14 of the refrigerator compartment 10. FIG. The air blower 20a includes, for example, a cross flow fan (a fan that blows airflow in a direction perpendicular to the direction in which the airflow is sucked). The blower 20 is an example of the “first blower” in the present invention. The blower 20a is an example of the “first blower” in the present invention.

  As a result, in the boundary region 10b, the air flow P1 formed by the blower 20 (blower portion 20a) reaches the floor surface 14 of the refrigerator compartment 10, so that the heat along the X direction between the region 11 and the region 13 is increased. Movement is blocked. In addition, the ventilation part 20a is installed in the lower surface 15a of the ceiling part 15 corresponding to the X1 side of the boundary area | region 10b.

  Further, the refrigerated warehouse 100 is provided with an air blowing device 40 (air blowing unit 40a) that sucks cold air from a cooling device 50 described later to form an air curtain air flow P3 (hereinafter referred to as air flow P3). And the air blower 40 (blower part 40a) is comprised so that the airflow P3 may be blown down to the floor surface 14 of the refrigerator compartment 10. FIG. Moreover, the ventilation part 40a consists of a cross flow fan, for example. The blower 40 is an example of the “second blower” in the present invention. The blower 40a is an example of the “third blower” in the present invention.

  As a result, in the boundary region 10c, the air flow P3 formed by the blower 40 (blower 40a) reaches the floor surface 14 of the refrigerator compartment 10, so that the heat along the X direction between the region 12 and the region 13 is increased. Movement is blocked. In addition, the ventilation part 40a is installed in the lower surface 15a of the ceiling part 15 corresponding to the X2 side of the boundary area | region 10c.

  As shown in FIG. 1, in the region 11 in the refrigerator compartment 10, in addition to the blower device 20, a cooling device 30 having a cooling function for cooling the region 11 and maintaining the temperature T <b> 1 together with the blower function is installed. Yes. Similarly, in the area 12, in addition to the air blower 40, a cooling device 50 having a cooling function for cooling the area 12 and maintaining the temperature T2 together with the air blowing function is installed. Specifically, the cooling device 30 is installed on the upstream side (X1 side) from the suction port 21a for sucking the cold air circulation flow G1 in the blower device 20 (blower portion 20a). It is installed on the upstream side (X2 side) from the suction port 41a for sucking the cold air circulation flow G2 in the (air blowing part 40a). The cooling device 30 and the cooling device 50 are examples of the “first cooling device” and the “second cooling device” in the present invention, respectively.

  Thereby, in the area | region 11, the cold air circulation flow G1 containing the airflow P1 for operating the air blower 20 (blower part 20a) and the cooling device 30 and thermally dividing the inside of the refrigerator compartment 10 is formed. Moreover, in the area | region 12, the cold air circulation flow G2 containing the airflow P3 for operating the air blower 40 (blower part 40a) and the cooling device 50, and thermally dividing the inside of the refrigerator compartment 10 is formed. It is configured.

  Here, the flow of airflow (cold air) in the region 11 will be described. As shown in FIG. 1, in the region 11, the cool air cooled by the cooling device 30 and blown out from the air outlet 32 of the cooling device 30 is transmitted along the lower surface 15 a of the ceiling portion 15 in the X2 direction (horizontal direction). 20 (suction part 20a) is sucked into the suction port 21a. The cold air changes its direction and is blown obliquely downward from the blower 20a of the blower 20 as an air flow P1. That is, the air outlet 22a of the blower 20a has an opening shape that forms the airflow P1 in which the cool air that is blown out travels toward the region 11 by a predetermined angle from directly below. Thereafter, the air flow P1 reaches the floor surface 14 and then changes its direction so that most of the airflow P1 is circulated along the X1 direction. Further, the air flow P1 is sucked into the suction port 31 of the cooling device 30 along the vicinity of the side wall 16a on the X1 direction side (upward in the Z1 direction). In this way, a cold air circulation flow G1 that circulates greatly in the clockwise direction is formed in the region 11.

  In addition, the flow of air (cold air) (cold air circulation flow G2) in the region 12 is the same as the flow of air (cold air) (cold air circulation flow G1) in the region 11. That is, the cool air cooled by the cooling device 50 and blown out from the outlet 52 of the cooling device 50 is sucked into the suction port 41a of the blower device 40 (blower portion 40a). The cold air changes its direction and becomes an airflow P3 from the air outlet 42a of the air blower 40a of the air blower 40 and is blown obliquely downward. The airflow P3 is sucked into the suction port 51 of the cooling device 50 along the vicinity of the side wall 16b on the X2 direction side (upward in the Z1 direction). Thus, in the region 12, a cold air circulation flow G2 that circulates largely counterclockwise is formed.

  Here, in 1st Embodiment, the air blower 20 is arrange | positioned at intervals in the X2 direction with the ventilation part 20a, and while being able to wind in part of the airflow P1, between area | region 11 and area | region 12 The air blower 20b is formed so as to form an air curtain airflow P2 (hereinafter referred to as an airflow P2) that flows into the region 13 in which the article 3 is refrigerated and stored. In addition, the ventilation part 20b is installed in the lower surface 15a of the ceiling part 15 corresponding to the X2 side of the boundary area | region 10b. Moreover, the ventilation part 20b consists of a crossflow fan, for example. The air blower 20b is an example of the “second air blower” in the present invention.

  Moreover, in 1st Embodiment, the air blower 40 is arrange | positioned at intervals in the X1 direction with the ventilation part 40a, and while being able to wind a part of airflow P3, it is the air curtain airflow P4 which flows in into the area | region 13. It is comprised so that the ventilation part 40b which forms (henceforth the airflow P4) may be included. In addition, the ventilation part 40b is installed in the lower surface 15a of the ceiling part 15 corresponding to the X1 side of the boundary area | region 10c. Moreover, the ventilation part 40b consists of a cross flow fan, for example. Then, by adjusting the air volume of each of the airflow P3 formed by the blower 20b and the airflow P4 formed by the blower 40b, a part of the airflow P1 and a part of the airflow P3 are entrained, thereby causing the region 13 to flow. It is configured to adjust the temperature of the. A detailed description of the adjustment of the temperature of the region 13 will be described later. The blower 40b is an example of the “fourth blower” in the present invention.

  Here, the flow of airflow (cold air) in the region 13 will be described. As shown in FIG. 1, in the region 13, the air flow P <b> 2 is blown obliquely downward from the blower 20 b of the blower 20. That is, the blower outlet 22b has an opening shape that forms the airflow P2 in which the blown cold air is directed toward the region 13 by a predetermined angle from directly below. After that, the airflow P2 reaches the floor surface 14 and then changes its direction so that most of the airflow P2 is circulated along the floor surface 14 in the X2 direction. Moreover, the airflow P2 collides (mixes) with the airflow P4 blown out from the blower 40b of the blower 40, and moves upward (Z1 direction). Thereafter, the airflow P2 is sucked into the suction port 21b of the blower 20b. In this way, a cold air circulation flow G3 that circulates in a counterclockwise direction is formed in the region 13. Similarly, after the airflow P4 blown out from the blower 40b (blower 42b) of the blower 40 collides (mixes) with the airflow P2, the airflow P4 moves upward (in the Z1 direction) and moves to the suction port 41b of the blower 40b. Sucked into. In this way, the region 13 is formed with the cold air circulation flow G4 that circulates greatly in the clockwise direction.

  In addition, when the refrigerator compartment 10 is viewed in a plan view, as shown in FIG. 2, the blower 20 (the blower 20a and the blower 20b) installed in the vicinity of the boundary between the region 11 and the region 13 has an internal space 10a. Is installed from the side wall 17a on one side (Y1 side) to the side wall 17b on the other side (Y2 side). In this case, four air blowers 20 (the air blowing part 20a and the air blowing part 20b) whose Y direction is the longitudinal direction are linearly arranged along the Y direction on the lower surface 15a of the ceiling part 15. Moreover, since the air blower 40 also has the same structure as the air blower 20, description is abbreviate | omitted.

  Further, under the lower surface 15a of the ceiling portion 15 in the vicinity of the side wall portion 16a (X1 side) of the region 11, two cooling devices 30 whose Y direction is the longitudinal direction are linearly arranged in the Y direction. Thereby, it is comprised so that the cold air blown out from each blower outlet 32 of the two cooling devices 30 may be sucked into each suction inlet 21a of the four blower devices 20 (blower part 20a). Note that the number and arrangement of the blower devices 40 and the cooling devices 50 installed on the region 12 side are also symmetrical with the region 11 side.

  Further, as a control configuration for maintaining the temperature in the refrigerator compartment 10 in the refrigerator warehouse 100, a controller device 70 is installed outside the refrigerator warehouse 100 as shown in FIG. The controller device 70 is provided with an overall control unit 71, a blower control unit 72, a cooling device control unit 73, a blower control unit 74, and a cooling device control unit 75. Here, the blower control units 72 and 74 have a function of controlling the operation of the blowers 20 and 40, respectively. In addition, the cooling device control units 73 and 75 have a function of controlling the operation of the cooling devices 30 and 50, respectively.

  As shown in FIGS. 1 and 3, the blower 20 is provided with temperature sensors 81a and 81b that detect the temperatures of the airflow P1 and the airflow P2 formed by the blower 20a and the blower 20b, respectively. . The blower 40 is provided with temperature sensors 82a and 82b that detect the temperatures of the airflow P3 and the airflow P4 formed by the blower 40a and the blower 40b, respectively. Further, the refrigerator compartment 10 is provided with a temperature sensor 83 that detects the temperature of the region 13. The temperature sensors 81a and 81b, the temperature sensors 82a and 82b, and the temperature sensor 83 are electrically connected to the overall control unit 71. The temperature sensor 83 is an example of the “temperature measurement unit” in the present invention.

  Then, the overall control unit 71 performs predetermined calculation processing based on the temperature of the air flow P1 by the temperature sensor 81a, and the blower control unit 72 and the cooling device control unit 73 receive commands based on the calculation processing result. Then, the operation control (fan speed control) of the air blower 20 (the air blower 20a) is performed based on the command of the air blower control unit 72, and the operation of the cooling device 30 is performed based on the command of the cooling device control unit 73. Control is performed. The same control configuration as described above is also applied to the region 12 side. Thereby, the cooperative operation of the air blower 20 and the cooling device 30 is performed, and the region 11 where the article 1 is stored is maintained at the temperature T1. Similarly, the region 12 where the article 2 is stored is maintained at the temperature T <b> 2 through the cooperative operation of the blower 40 (the blower 40 a) and the cooling device 50.

  Next, the adjustment of the temperature of the region 13 will be described in detail with reference to FIG.

  In the first embodiment, based on the temperature measured by the temperature sensor 83, the air volume of each of the air stream P2 formed by the blower 20b of the blower 20 and the airflow P4 formed by the blower 40b of the blower 40 is shown. Is adjusted to adjust the temperature of the region 13. This will be specifically described below.

(When the measured temperature is the target temperature)
When the temperature measured by the temperature sensor 83 is a target temperature (temperature T3, for example, −18 ° C.) (in the vicinity of the target temperature), the rotational speed of the fan of the blower 20a of the blower 20 is The rotational speed of the fan of the blower 20b is made substantially equal. In this case, the air flow P1 is blown out to the region 11 side, and the air flow P2 is blown out to the region 13 side, and it is not nearly mixed (heat exchange) with each other. Thereby, the area | region 11 and the area | region 13 will be in the state mutually insulated in the boundary area | region 10b (state which does not heat-exchange). Similarly, the rotational speed of the fan of the blower 40a of the blower 40 and the rotational speed of the fan of the blower 40b are substantially equal.

(When the measured temperature is higher than the target temperature)
When the temperature measured by the temperature sensor 83 is higher than the target temperature (temperature T3, for example, −18 ° C.), the rotational speed of the fan of the blower 20b of the blower 20 is increased. Thereby, a part of the relatively low temperature (temperature T1, for example, −20 ° C.) airflow P1 blown out from the blower 20a is caught (mixed) in the airflow P2. As a result, the temperature in the region 13 decreases, and the temperature in the region 13 approaches the target temperature.

(When the measured temperature is lower than the target temperature)
When the temperature measured by the temperature sensor 83 is lower than the target temperature, the rotational speed of the fan of the blower 40b of the blower 40 is increased. As a result, a part of the relatively high temperature (temperature T2, for example, −15 ° C.) air flow P3 blown out from the blower 40a is caught (mixed) in the air flow P4. As a result, the temperature in the region 13 rises, and the temperature in the region 13 is brought close to the target temperature. Thus, the temperature in the region 13 is maintained at the target temperature. That is, the two cooling devices 30 and 50 form the region 11, the region 12, and the region 13 that are held at three different temperatures T 1, T 2, and T 3, respectively, in the refrigerator compartment 10.

  As shown in FIG. 2, an opening / closing door 18 a is provided on the side wall portion 17 a (Y1 side) on the region 11 side, and an opening / closing door 18 b is provided on the side wall portion 17 a on the region 12 side. An opening / closing door 18c is provided on the side wall portion 17a on the region 13 side. In addition, on the outside of the refrigerator compartment 10, a loading space 101 for temporarily placing the articles 1, 2 and 3 is provided. The loading space 101 has a predetermined height with respect to the ground, and is configured such that the truck 110 can come in contact with the ground. In this way, the refrigerated warehouse 100 is configured.

  In the first embodiment, the following effects can be obtained.

  In the first embodiment, as described above, a part of the airflow P1 can be engulfed, and the air blowing unit 20b that forms the airflow P2 flowing into the region 13 provided between the region 11 and the region 12; A part of the air flow P3 can be entrained, and the air blower 40b that forms the air flow P4 flowing into the region 13 is included. Thereby, even if it does not provide a cooling device in the area | region 13, the area | region 13 can be cooled by the airflow P2 which included some airflows P1, and the airflow P4 which included some airflows P3. As a result, unlike the case where a cooling device is provided in each of the regions 11, 12, and 13, the regions 11, 12, and 13 can be cooled while suppressing the complexity of the configuration. In addition, since the region 13 can be cooled by the cold air in which the airflow P2 and the airflow P4 are mixed without providing a duct or the like in the region 13, the configuration is complicated because there is no need to provide a duct or the like in the region 13. It is possible to cool the region 11, the region 12, and the region 13 while suppressing this.

  In the first embodiment, as described above, a part of the airflow P1 and the airflow are adjusted by adjusting the air volume of each of the airflow P2 formed by the air blower 20b and the airflow P4 formed by the air blower 40b. The temperature of the region 13 is adjusted by involving a part of P3. Thereby, a part of airflow P1 and a part of airflow P3 can be easily involved.

  In the first embodiment, as described above, the temperature sensor 83 provided in the region 13 is further provided. Based on the temperature measured by the temperature sensor 83, the airflow P2 and the air blower 40b formed by the air blower 20b. The temperature of the region 13 is adjusted by entraining a part of the airflow P1 and a part of the airflow P3 by adjusting the air volume of each of the airflows P4 formed by the above. Thereby, based on the temperature measured by the temperature sensor 83, the temperature of the region 13 can be easily maintained at a constant temperature.

(Second Embodiment)
Next, a second embodiment will be described with reference to FIGS. 4 and 5. In the second embodiment, a heat exchanging unit 90 that performs heat exchange between the airflow P2 flowing into the region 13 and the airflow P4 is provided. In the drawing, the same reference numerals as those in the first embodiment are attached to the same components as those in the first embodiment.

  In the refrigerated warehouse 200 according to the second embodiment of the present invention, as shown in FIG. 4, the refrigeration room 10 is provided with a heat exchanging unit 90 that performs heat exchange between the airflow P2 flowing into the region 13 and the airflow P4. Yes. The heat exchange part 90 is installed on the lower surface 15 a of the ceiling part 15 corresponding to the region 13. The heat exchanging unit 90 is provided with a suction port 90a. The suction port 90 a is provided on the lower side (Z2 direction side) of the heat exchange unit 90. And the heat exchange part 90 is comprised so that the airflow P2 and the airflow P4 which move upward from the floor surface 14 may be sucked in via the suction inlet 90a. And in the heat exchange part 90, it is comprised so that heat exchange may be performed between the airflow P2 and the airflow P4 which were suck | inhaled from the suction inlet 90a. Thereby, the temperature difference between the temperature of the airflow P2 and the temperature of the airflow P4 becomes small (substantially uniform).

  Further, the heat exchanging unit 90 is provided with an air outlet 90b. The blower outlet 90b is provided in the side (X1 direction and X2 direction) of the heat exchange part 90. FIG. And the heat exchange part 90 makes the air blower 20 (blower part 20b) side and the air blower 40 (blower part) the air flow P2 and the air flow P4 which were mutually made temperature uniform by heat exchange via the blower outlet 90b. 40b).

  Further, when the heat exchange unit 90 is viewed in a plan view, as shown in FIG. 5, a plurality of (two in the second embodiment) heat exchange units 90 are installed along the Y direction. Further, the plurality of heat exchange units 90 are arranged along the Y direction with a predetermined interval therebetween. In addition, the other structure of 2nd Embodiment is the same as that of the said 1st Embodiment.

  In the second embodiment, the following effects can be obtained.

  In the second embodiment, as described above, the heat exchange unit 90 that is provided in the region 13 and performs heat exchange between the airflow P2 flowing into the region 13 and the airflow P4 is provided. As a result, the temperature difference between the temperature of the airflow P2 flowing into the region 13 and the temperature of the airflow P4 can be reduced (substantially equal), so that the temperature variation in the region 13 is reduced (substantially uniform). be able to.

(Third embodiment)
Next, a third embodiment will be described with reference to FIG. In the third embodiment, unlike the second embodiment, the heat exchanging portion 91 is configured such that a refrigerant flows therethrough. In the drawing, the same reference numerals as those in the first embodiment are attached to the same components as those in the first embodiment.

  As shown in FIG. 6, the refrigerated warehouse 300 according to the third embodiment of the present invention is configured such that the heat exchange unit 91 circulates (is supplied) with refrigerant. The heat exchanging unit 91 is configured to perform heat exchange between the airflow P2 and the airflow P4 flowing into the region 13, and to cool the airflow P2 and the airflow P4 with a refrigerant. Further, the temperature of the refrigerant is configured to be lower (for example, −25 ° C.) than the temperature T1 of the region 11 and the temperature T2 of the region 12.

  In the third embodiment, the following effects can be obtained.

  In the third embodiment, as described above, the heat exchanging portion 91 is configured so that the refrigerant flows, and the air exchange P91 and the air flow P4 flowing into the region 13 are respectively transferred to the heat exchanging portion 91 by the refrigerant. Configure to cool. Here, when the refrigerant does not flow through the heat exchanging portion 91, the adjustable temperature in the region 13 is limited to a temperature range (T1 or more and T2 or less) between the temperature T1 of the airflow P1 and the temperature T2 of the airflow P3. It is done. Therefore, as described above, the airflow P2 and the airflow P4 are each cooled by the refrigerant, so that the temperature range between the temperature T1 of the airflow P1 and the temperature T2 degrees of the airflow P3 (T1 or more and T2 or less). ) And the temperature of the region 13 can be adjusted.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above description of the embodiments but by the scope of claims for patent, and further includes all modifications within the meaning and scope equivalent to the scope of claims for patent.

  For example, in the first to third embodiments, the example in which the cooling device is arranged below the lower surface of the ceiling portion has been described, but the present invention is not limited to this. For example, you may arrange | position a cooling device in the side wall part of a refrigerator compartment. In addition, a cooling device may be arranged outside the refrigerator compartment, and cold air may be sucked in and blown out from the inlet and outlet of the cold air provided on the wall surface of the refrigerator compartment.

  Moreover, although the said 1st-3rd embodiment showed about the example using a total of 8 air blowers (a total of 16 air blow parts) and a total of 4 cooling devices, this invention is limited to this. Absent. The combination of the number of blowers and the number of cooling devices may be a combination other than the above embodiment.

  Moreover, although the said 1st-3rd embodiment showed about the example in which three area | regions from which temperature differs mutually were formed in the refrigerator compartment, this invention is not limited to this. For example, three or more regions having different temperatures may be formed in the refrigerator compartment by increasing the number of blowers and cooling devices.

  Moreover, in the said 1st-3rd embodiment, although the example which adjusts the temperature of the area | region 13 by adjusting each of the airflow P2 and the airflow P4 was shown, this invention is not limited to this. For example, the temperature of the region 13 may be adjusted by adjusting the wind direction of the airflow P2 formed by the blower 20b (the airflow P4 formed by the blower 40b). In this case, when the temperature measured by the temperature sensor 83 is higher than the target temperature, the wind direction of the airflow P2 is adjusted so that the airflow P2 formed by the blower 20b approaches the airflow P1. Thereby, a part of airflow P1 is caught in the airflow P2 (mixed). As a result, the temperature in the region 13 decreases, and the temperature in the region 13 approaches the target temperature. Further, when the temperature measured by the temperature sensor 83 is lower than the target temperature, the wind direction of the airflow P4 is adjusted so that the airflow P4 formed by the blower 40b approaches the airflow P3. Thereby, a part of airflow P4 is caught in the airflow P3 (mixed). As a result, the temperature in the region 13 rises, and the temperature in the region 13 is brought close to the target temperature.

  Moreover, in the said 1st-3rd embodiment, although the example which adjusts the temperature of the area | region 13 by adjusting each of the airflow P2 and the airflow P4 was shown, this invention is not limited to this. For example, the temperature of the region 13 may be adjusted by adjusting both the air volume and the air direction of each of the air current P2 and the air current P4. Moreover, you may adjust the temperature of the area | region 13 by methods other than adjustment of an air volume and a wind direction.

  Moreover, in the said 1st-3rd embodiment, about the example which raises the rotation speed of the fan of the ventilation part 20b (blower part 40b) by the side of the area | region 13, when measured temperature is higher than target temperature (when low). Although shown, the present invention is not limited to this. For example, when the measured temperature is higher (lower) than the target temperature, the rotational speed of the fan of the blower 20a (blower 40a) on the region 11 side (region 12 side) may be increased.

  Moreover, in the said 2nd and 3rd embodiment, although shown about the example which has arrange | positioned the heat exchange part under the lower surface of a ceiling part, this invention is not limited to this. For example, you may arrange | position a heat exchange part in the side wall part of a refrigerator compartment. In addition, the heat exchange unit may be arranged outside the refrigerator compartment, and cold air may be sucked in and blown out from the inlet and outlet of the cold air provided on the wall surface of the refrigerator compartment.

  Moreover, in the said 2nd and 3rd embodiment, although the example using a total of two heat exchange parts was shown, this invention is not limited to this. The number of heat exchange units may be other than two.

1 article (first article)
2 article (second article)
3 goods (3rd goods)
11 area (first article storage area)
12 areas (second article storage area)
13 area (third article storage area)
20 Blower (first blower)
20a Blower (first blower)
20b Blower (second blower)
40 Blower (second blower)
40a Blower (third blower)
40b Blower (fourth blower)
83 Temperature sensor (temperature measurement unit)
90, 91 Heat exchange unit 100, 200, 300 Refrigerated warehouse P1 Airflow (first air curtain airflow)
P2 airflow (second air curtain airflow)
P3 Airflow (3rd air curtain airflow)
P4 airflow (4th air curtain airflow)

Claims (5)

A first cooling device that supplies cold air to a first article storage area in which the first article is stored refrigerated;
A second cooling device for supplying cold air to a second article storage area in which the second article is stored refrigerated;
A first air blowing unit that sucks cold air from the first cooling device to form a first air curtain airflow, and a first air blowing unit are arranged at a distance from each other, and a part of the first air curtain airflow is A second air curtain airflow is formed that can be rolled up and that flows between the first article storage area and the second article storage area and flows into the third article storage area where the third article is stored refrigerated. A first air blower including a second air blower that
A third air blowing unit that sucks cold air from the second cooling device to form a third air curtain air flow, and a third air blowing unit are arranged at a distance from each other, and a part of the third air curtain air flow is arranged. A second air blower that includes a fourth air blower that can be entrained and that forms a fourth air curtain airflow that flows into the third article storage region ;
The second air blowing unit blows out the second air curtain airflow toward the lower side of the third article storage area and sucks the blown second air curtain airflow above the third article storage area. And is configured to form a circulation flow in the third article storage area,
The fourth air blowing section blows out the fourth air curtain airflow toward the lower side of the third article storage area, and sucks the blown out fourth air curtain airflow above the third article storage area. Thus , a refrigerated warehouse configured to form a circulation flow in the third article storage area . By adjusting at least one of the air volume and the wind direction of at least one of the second air curtain airflow formed by the second air blowing unit and the fourth air curtain airflow formed by the fourth air blowing unit , It is configured to adjust the temperature of the pre-Symbol third article storage area, cold storage of claim 1. A temperature measuring unit provided in the third article storage area;
Based on the temperature measured by the temperature measuring unit, the air volume of at least one of the second air curtain airflow formed by the second air blowing unit and the fourth air curtain airflow formed by the fourth air blowing unit. and by adjusting at least one of the wind direction, and is configured to adjust the previous SL temperature of the third article storage area, cold storage of claim 2. 2. A first heat exchanging unit that is provided in the third article storage area and performs heat exchange between the second air curtain airflow and the fourth air curtain airflow flowing into the third article storage area. The refrigerator warehouse of any one of -3. Provided in the third article storage region, and said third article storage region the fourth air curtain stream and the second air curtain stream flowing into, further comprising a second heat exchanger for cooling respectively by refrigerant, The refrigerated warehouse of any one of Claims 1-3 .

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