JP2011112267A - Refrigeration unit for container - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To sufficiently cool an invertor device and a reactor device and to provide configuration having superior total weight balance, in a refrigeration unit for a container including an invertor compressor. <P>SOLUTION: A condenser (31) is disposed at a central section in the vertical direction, of an outdoor storage space (S1) of this refrigeration unit (10) for the container in a state that an air inflow-side space (S11) is formed at a lower part and an air outflow-side space (S12) is formed at an upper part. The compressor (30), the invertor device (82) and the reactor device (83) are disposed at the inflow-side space (S11), and the compressor (30) and the reactor device (83) are respectively disposed at one side and the other side with respect to the center in the width direction, of the outdoor storage space (S1). <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

    The present invention relates to a container refrigeration apparatus, and particularly relates to an arrangement configuration of components.

    Conventionally, a container refrigeration apparatus that cools the inside of a container used for maritime transportation or the like is provided at an opening of a container body that is open at one end (see Patent Document 1). An outside storage space that communicates with the outside of the container body is formed in the lower portion of the casing body of the container refrigeration apparatus, and a compressor, a condenser, an outside fan, and the like are stored in the outside storage space. ing. On the other hand, in the upper part of the casing main body, an internal storage space communicating with the interior of the container main body is formed, and an internal storage fan and an evaporator are disposed in the internal storage space.

    During operation of the container refrigeration apparatus, the air in the container of the container body is guided into the storage space in the storage by the internal fan, and is cooled when passing through the evaporator. The cooled air flows out of the ventilation path and is sent again into the container body. As described above, in the container refrigeration apparatus, the inside air of the container is circulated while cooling to perform refrigeration or freezing in the inside of the container body.

Japanese Patent Laid-Open No. 9-24990

    By the way, in the conventional container refrigeration apparatus as shown in the above-mentioned Patent Document 1, a fixed capacity type compressor having a constant rotation speed is used as the compressor.

    On the other hand, the inventors of the present application have recently adopted a variable capacity compressor whose rotational speed is controlled by an inverter device so that the cooling capacity in the refrigerator can be adjusted with high accuracy. Therefore, it is necessary to newly add an inverter device and a reactor device to the conventional product, and these are arranged in an external storage space where a compressor is provided.

    However, since both the inverter device and the reactor device have heat-generating parts that generate heat at high temperatures during operation, it is necessary to cool them when adding both devices. In addition, since containers may tilt due to rolling during loading or transportation, when adding inverter devices and reactor devices, various components must be placed in a well-balanced manner so that the weight of the various components is not biased. It was necessary to rearrange.

    The present invention has been made in view of such a point, and in the container refrigeration apparatus provided with the inverter compressor, the inverter apparatus and the reactor apparatus can be sufficiently cooled and a weight-balanced arrangement configuration can be realized. With the goal.

    The first invention comprises a casing (4) having a partition member (2) attached to the opening end face of the container body (1) and dividing the external storage space (S1) and the internal storage space (S2); A compressor (30) provided in the external storage space (S1) and a heat source side heat exchanger (31) provided in the external storage space (S1) for exchanging heat between the external air and the refrigerant. A refrigeration apparatus for a container having a refrigerant circuit (20) for cooling the interior of the container, the inverter apparatus (82) for controlling the rotational speed of the compressor (30), and the compressor (30) And a reactor device (83) for suppressing a reverse phase current in the power supply circuit, and an air inflow side space (S11) is formed in the lower part of the central part in the vertical direction of the external storage space (S1). On the other hand, the heat source side heat exchanger (31) is provided so that an air outflow side space (S12) is formed above. The compressor (30), the inverter device (82), and the reactor device (83) are provided in the inflow side space (S11), and the compressor (30), the reactor device (83) Are arranged on one side and the other side with respect to the center in the width direction of the external storage space (S1).

    In the first invention, the inverter device (82) and the reactor device (83) each having a heat generating component are arranged on the upstream side of the air flow of the heat source side heat exchanger (31) that becomes a condenser during the cooling operation. . Therefore, the inverter device (82) and the reactor device (83) are arranged in a flow of air having a relatively low temperature before cooling the refrigerant of the condenser, and are cooled by releasing heat to the air. On the other hand, by placing the relatively heavy reactor device (83) on the opposite side to the installation side of the heavy compressor (30) with respect to the center in the width direction of the external storage space (S1), The weight balance is improved.

    The second invention further includes a cooler (42) that cools the inverter device (82) by the refrigerant that is provided in the refrigerant circuit (20) and flows through the refrigerant circuit (20) in the first invention, The inverter device (82) is disposed between the compressor (30) and the reactor device (83).

    In the second aspect of the invention, the inverter device (82) has a relatively low heat resistant temperature compared to the reactor device (83). Therefore, by providing the cooler (42), the inverter device (82) can be cooled not only by the air outside the warehouse but also by the refrigerant flowing through the refrigerant circuit (20). Further, the refrigerant circuit (20) is usually provided in the vicinity of the compressor (30), but by providing the inverter device (82) between the compressor (30) and the reactor device (83), the inverter device ( 82) is provided near the refrigerant circuit (20). Therefore, when the inverter device (82) is arranged at a position far from the compressor (30), the refrigerant pipe is used to cool the inverter device (82) by the cooler (42) provided in the refrigerant circuit (20). Needs to be extended toward the inverter device (82). However, by installing the inverter device (82) near the refrigerant circuit (20) as described above, it is not necessary to extend the refrigerant pipe unnecessarily.

    3rd invention is equipped with the external fan (35) which forms the air flow which passes the said heat-source side heat exchanger (31) in 1st or 2nd invention, The said external fan (35) It is provided in the outflow side space (S12), and is provided at a side position corresponding to the reactor device (83) across the heat source side heat exchanger (31). The reactor device (83) (83d).

    In the third aspect of the invention, the outside fan (35) is provided in the outflow side space (S12) and is provided at a side position corresponding to the reactor device (83) with the heat source side heat exchanger (31) interposed therebetween. It has been. The reactor device (83) is provided with heat radiating fins (83d). Therefore, the reactor device (83) is located close to the external fan (35) and is located at a relatively high speed of the air flow formed by the external fan (35), and radiates heat from the heat radiating fin (83d). Effective cooling. Further, by disposing the external fan (35) as described above, the external fan (35) is disposed on the reactor device (83) side having a weight smaller than that of the compressor (30) in the width direction. It will be. Therefore, the load on the compressor (30) side in the width direction can be reduced.

    According to a fourth invention, in any one of the first to third inventions, the external storage space (S1) is a width of the heat source side heat exchanger (31) and the heat source side heat exchanger (31). The inflow side space (S11) and the outflow side space (S12) are partitioned by a partition member (91) provided at one end in the direction, and the inverter device (82) and the reactor device (83) Is disposed below the heat source side heat exchanger (31), while the compressor (30) is disposed below the partition member (91).

    In the fourth aspect of the invention, the inverter device (82) having the heat generating component and the reactor device (83) are disposed below the heat source side heat exchanger (31), so that the heat source side heat exchanger (31) is provided. The inverter device (82) and the reactor device (83) are effectively cooled by the inflowing air. On the other hand, the width of the heat source side heat exchanger (31) is made shorter than the width of the external storage space (S1) and placed so as not to reach the upper side of the compressor (30), thereby compressing in the width direction. The load on the machine (30) side can be reduced.

    According to the present invention, the inverter device (82) having the heat generating component and the reactor device (83) are arranged on the upstream side of the air flow of the heat source side heat exchanger (31), whereby the inverter device (82) and the reactor device (83) are arranged. The device (83) can be installed at a location where it can be sufficiently cooled. In addition, by installing the relatively heavy reactor device (83) on the side opposite to the installation side of the heavy compressor (30) with the center in the width direction of the external storage space (S1) as the reference, The weight balance can be improved. That is, according to the present invention, the inverter device (82) and the reactor device (83) can be sufficiently cooled, and an arrangement configuration having an excellent overall weight balance can be realized.

    Moreover, according to 2nd invention, an inverter apparatus (82) can be cooled effectively with the air outside a store | warehouse | chamber, and the refrigerant | coolant of a refrigerant circuit (20). Further, by disposing the inverter device (82) near the refrigerant circuit (20), the cooler (42) for cooling the inverter device (82) can be easily installed without unnecessarily extending the refrigerant pipe. .

    Further, according to the third invention, the external fan (35) is provided at the side position corresponding to the reactor device (83) with the heat source side heat exchanger (31) sandwiched in the inflow side space (S11). Since the heat dissipating fins (83d) are provided in the device (83), the reactor device (83) can be effectively cooled by being disposed at a location where the air flow of the external fan (35) is relatively high. Moreover, since the outside fan (35) is arrange | positioned at the reactor apparatus (83) side with a weight smaller than a compressor (30) regarding the width direction by arrange | positioning as mentioned above, a compressor (30 ) Side load can be reduced, and the weight balance can be further improved.

    According to the fourth invention, the inverter device (82) having the heat generating component and the reactor device (83) are arranged below the heat source side heat exchanger (31), so that the inverter device (82) and the reactor device are arranged. The device (83) can be effectively cooled by the air flowing into the heat source side heat exchanger (31). In addition, the width of the heat source side heat exchanger (31) is formed to be shorter than the width of the external storage space (S1) so that the heat source side heat exchanger (31) does not reach above the compressor (30). By arranging, the load on the compressor (30) side in the width direction can be reduced, and the weight balance can be further improved.

FIG. 1 is a refrigerant circuit diagram of a container refrigeration apparatus according to the present invention. FIG. 2 is a view of the container refrigeration apparatus according to the present invention as viewed from the outside of the warehouse. FIG. 3 is a longitudinal sectional view of the container refrigeration apparatus according to the present invention. FIG. 4 is a diagram illustrating an arrangement configuration in the inflow side space. FIG. 5 is an enlarged view of a mounting portion between the inverter device and the cooler. FIG. 6 is a diagram showing an arrangement configuration in the outflow side space.

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

    The container refrigeration apparatus (10) cools (refrigerates or freezes) the inside of a container used for land transportation, sea transportation, and the like, and includes a refrigerant circuit (20) and is a vapor compression refrigeration cycle. I do.

    As shown in FIG. 1, the refrigerant circuit (20) includes a main circuit (21), a defrost hot gas bypass passage (22), and a supercooling bypass passage (23) for refrigerant supercooling.

    The main circuit (21) includes a compressor (30), a condenser (31), an electric main expansion valve (32) as an expansion mechanism, and an evaporator (33) in series by a refrigerant pipe (34) in order. Connected and configured. And although the said compressor (30) is not shown in figure, the rotation speed is controlled by an inverter, the rotation speed is controlled in multiple steps, and the operation capacity is variable. The condenser (31) is provided with an external fan (35), while the evaporator (33) is provided with an internal fan (36). The internal fan (36) is configured to supply the cooling air cooled by the evaporator (33) into the internal space.

    An oil separator (40) is provided on the discharge side of the compressor (30), and a discharge pressure adjusting valve (38) is provided between the oil separator (40) and the condenser (31). Yes. A receiver (41), a cooler (42), a dryer (43), and a plate heat exchanger (44) are provided in this order between the condenser (31) and the main expansion valve (32). Yes. The oil return pipe (40a) of the oil separator (40) is connected to the supercooling bypass path (23). The cooler (42) is provided so as to come into contact with a power element (82c) that generates heat at a high temperature of an inverter device (82), which will be described later, or through a heat transfer member, and flows through the condenser (31). The power element (82c) is cooled by the liquid refrigerant. The dryer (43) is configured to remove moisture from the liquid refrigerant that has flowed through the condenser (31).

    The plate heat exchanger (44) supercools the liquid refrigerant that has flowed through the condenser (31), and includes a primary side passage (45) and a secondary side passage (46). The primary side passage (45) is connected to the main circuit (21), and the secondary side passage (46) is connected to the supercooling bypass passage (23). The inflow end of the supercooling bypass passage (23) is connected to the refrigerant pipe (34) between the cooler (42) and the dryer (43), and the outflow end of the supercooling bypass passage (23) is compressed. It is connected to the compression chamber in the intermediate pressure state in the machine (30).

    Furthermore, a first on-off valve (47) and an electric supercooling expansion valve (48) as an expansion mechanism are provided on the inflow side of the supercooling bypass passage (23). Corresponding to the first on-off valve (47), the main circuit (21) is provided with a second on-off valve (49) between the branch portion of the supercooling bypass passage (23) and the dryer (43). ing.

    The plate heat exchanger (44) branches from the main circuit (21) to the supercooling bypass passage (23) and is decompressed by the supercooling expansion valve (48) and the refrigerant flowing through the main circuit (21). And the refrigerant that flows through the main circuit (21) through heat exchange are supercooled.

    The hot gas bypass path (22) includes a common path (50), and a first bypass path (51) and a second bypass path (52) branched from the common path (50). The common path (50) has an inflow end connected between the oil separator (40) and the condenser (31), and is provided with a third on-off valve (53). Outflow ends of the first bypass path (51) and the second bypass path (52) are connected between the main expansion valve (32) and the evaporator (33), and the second bypass path (52) A drain pan heater (54) for heating the drain pan disposed at the lower portion of the evaporator (33) is provided.

    The hot gas bypass path (22) is configured to supply high-temperature and high-pressure gas refrigerant discharged from the compressor (30) to the evaporator (33) during the defrost operation when the evaporator (33) is frosted. Has been. The second bypass passage (52) is configured to heat the drain pan during the defrost operation.

    Next, sensors provided in the refrigerant circuit (20) will be described.

    The discharge side and suction side of the compressor (30) are provided with a high pressure sensor (60) and a high pressure switch (61) for detecting the discharge gas pressure of the compressor (30), and the compressor A low pressure sensor (62) for detecting the suction gas pressure of (30) is provided. A discharge temperature sensor (63) and a suction temperature sensor (64) for detecting the refrigerant temperature are provided on the discharge side and the suction side of the compressor (30).

    An inflow temperature sensor (65) and an outflow temperature sensor (66) for detecting the refrigerant temperature are provided on the inflow side and the outflow side of the secondary passage (46) of the plate heat exchanger (44). .

    An inflow temperature sensor (67) and an outflow temperature sensor (68) for detecting the refrigerant temperature are provided on the inflow side and the outflow side of the evaporator (33).

    The condenser is provided with an outside air temperature sensor (69) that detects the outside air temperature that is the intake temperature of the condenser. Further, an intake temperature sensor (70) for detecting the intake air temperature and an outlet temperature sensor (71) for detecting the blown air temperature are provided on the air suction side and the blowout side of the evaporator.

    The container refrigeration apparatus (10) is provided with a controller (80) for controlling the cooling operation by controlling the refrigerant circuit (20). The controller (80) receives signals from the high pressure sensor (60), etc., and controls the control board (81a) for controlling the cooling operation and the rotational speed of the compressor (30). Inverter control board (82a) and the like are provided. In addition, although mentioned later for details, the said control board (81a) is installed in the electrical equipment box (81) mentioned later, and the said inverter control board (82a) is in the inverter box (82b) of an inverter apparatus (82). It is installed (see Fig. 2).

    Next, the structure of the container refrigeration apparatus (10) will be described.

    As shown in FIG.2 and FIG.3, the said container refrigeration apparatus (10) is attached so that the opening end surface of the container main body (1) formed in the rectangular box body may be plugged up. The container refrigeration apparatus (10) includes a casing body (2) that partitions the outside of the container outside the container and the inside of the container inside the container, and a partition provided on the back side (inside of the container) of the casing body (2). A casing (4) provided with a plate (3) and the like is provided.

    The casing body (2) is formed in a double structure of an aluminum inner casing (2a) and an FRP outer casing (2b), and a heat insulating layer (2c) made of a foaming agent is formed inside. ing. In addition, the casing body (2) constitutes a bulging portion (5) whose lower portion bulges toward the inner side of the container main body (1), and an outside storage space is provided outside the bulging portion (5). While (S1) is partitioned, the storage space (S2) located above the bulging portion (5) is partitioned on the upper rear surface (inside the storage).

    The partition plate (3) is formed in a single plate shape, and is attached so as to cover the rear of the casing body (2). The storage space (S2) is partitioned between the upper part of the casing body (2) and the partition plate (3), while the lower part (the bulging part (5)) of the casing body (2). An air passage (S3) is formed between the partition plate (3) and the partition plate (3). The upper end of the air passage (S3) communicates with the internal storage space (S2), while the lower end communicates with the interior.

    The external storage space (S1) includes a compressor (30), a condenser (31), an oil separator (40), a receiver (41), a cooler (42), a dryer (43), and a plate heat exchanger. A part of the refrigerant circuit (20) to which (44) and the like are connected, an external fan (35), and a ventilator (90) are housed. The external storage space (S1) includes a reactor (81) connected to the power supply circuit of the electrical component box (81), the inverter device (82), and the compressor (30) to suppress an equivalent reverse phase current ( A reactor device (83) having 83a) is housed. On the other hand, the evaporator (33) and the internal fan (36) are stored in the internal storage space (S2).

    Hereinafter, the arrangement configuration of the external storage space (S1) will be described in detail.

    A condenser (31) is provided at the center in the vertical direction of the external storage space (S1). The condenser (31) is constituted by a fin-and-tube heat exchanger having a plurality of tubes extending in the width direction (left-right direction in FIG. 2) of the external storage space (S1). A plate-like partition member (91) is provided on one end side in the width direction of the condenser (31) (right end side in FIG. 2), and the external storage space (S1) is separated from the condenser (31). It is divided into two upper and lower spaces by the member (91). Specifically, an inflow side space (S11) into which air flowing into the condenser (31) is introduced from outside the compartment is defined below the condenser (31) and the partition member (91), and the condenser (31) And the outflow side space (S12) into which the air which flowed out from the condenser (31) flows in is divided above the partition member (91).

    As shown in FIGS. 2 to 4, the inflow side space (S11) includes the compressor (30), the oil separator (40), the receiver (41), the plate heat exchanger (44), and Are connected to a part of the refrigerant circuit (20), an inverter device (82), and a reactor device (83).

    The compressor (30) and the reactor device (83) are respectively arranged on one side and the other side with respect to the center in the width direction of the external storage space (S1). The inverter device (82) is disposed between the compressor (30) and the reactor device (83). The inverter device (82) and the reactor device (83) are disposed below the condenser (31), while the compressor (30) is disposed below the partition member (91).

    The inverter device (82) includes the inverter control board (82a) and an inverter box (82b) that covers the inverter control board (82a). On the inverter control board (82a), a power element (82c) that generates heat to a high temperature during operation is mounted. In the present embodiment, the inverter box (82b) is formed of a material having excellent thermal conductivity such as aluminum. In addition, the inverter box (82b) has a back surface (upper surface in FIG. 4) abutting against the outer surface of the bulging portion (5) of the casing body (2) (the FRP outer casing (2b)). It is provided as follows. Furthermore, the said cooler (42) is attached to the surface facing the compressor (30) of an inverter box (82b). The cooler (42) is provided at a position corresponding to the power element (82c) across the inverter box (82b) (see FIG. 5).

    The cooler (42) has two concave grooves formed on one surface, the other surface is formed on a flat mounting surface, and is made of aluminum. A part of the refrigerant pipe (34) (copper pipe) of the refrigerant circuit (20) is fitted in the two concave grooves of the cooler (42) (see FIG. 5). The cooler (42) is electrodeposited with a part of the refrigerant pipe (34) fitted therein. Specifically, the mounting surface is masked and immersed in a water-soluble paint, the cooler (42) is used as a cathode, direct current is passed between the counter electrode and electrodeposition is performed by electrophoresis to form a coating film. Let it form. Thereby, while being able to adhere a coating film to detail, since the cationic electrodeposition coating which uses a to-be-coated object as a cathode is used, corrosion resistance can be improved.

    The power element (82c) generating heat at a high temperature of the inverter device (82) dissipates heat to the inverter box (82b), and the inverter box (82b) passes through the cooler (42) to the two refrigerant pipes (34). It is cooled by dissipating heat to the high-pressure liquid refrigerant flowing through. The power element (82c) radiates heat to the inverter box (82b), and the inverter box (82b) radiates heat to the outside air flowing toward the condenser (31), or the inverter box (82b) Heat is dissipated to (2), and the casing body (2) is also cooled by dissipating heat to the air outside the cabinet.

    The reactor device (83) includes the reactor (83a) and a reactor cover (83b) that covers the reactor (83a). In this embodiment, the reactor (83a) is attached so as to contact the inner surface of the bulging portion (5) of the casing body (2) (the outer surface of the FRP outer casing (2b)).

    The reactor cover (83b) is made of a material having excellent thermal conductivity such as aluminum, and is formed in a rectangular box having an open rear surface (upper surface in FIG. 4). The reactor cover (83b) has a casing body so that the inner surface (upper surface in FIG. 4) of the front plate (83c) contacts the front surface (lower surface in FIG. 4) of the reactor (83a). It is attached to the bulging part (5) of (2). Further, heat radiation fins (83d) are provided on the outer surface (the lower surface in FIG. 4) of the front plate (83c) of the reactor cover (83b). The radiating fin (83d) extends in the vertical direction so as to follow the direction of the air flow flowing into the condenser (31). The radiating fin (83d) may be formed integrally with the front plate (83c) of the reactor cover (83b), or may be formed separately.

    With the above configuration, the reactor (83a) that generates heat at a high temperature radiates heat from the rear surface of the reactor (83a) to the casing body (2). The casing body (2) is cooled by releasing heat to the outside air. The reactor (83a) also radiates heat from the front surface of the reactor (83a) to the radiation fins (83d) and the casing body (2) via the reactor cover (83b). The reactor cover (83b) and the radiation fins (83d) are cooled by releasing heat to the air flowing into the condenser (31). In this way, the reactor (83a) radiates heat to the outside air via the casing body (2), and flows into the condenser (31) via the reactor cover (83b) and the radiating fins (83d). It is cooled by dissipating heat to the air.

    On the other hand, as shown in FIGS. 2, 3, and 6, the outflow side space (S12) includes a part of the refrigerant circuit (20) to which the dryer (43) is connected and the electrical component box (81). The outside fan (35) and the ventilator (90) are provided.

    A part of the refrigerant circuit (20) to which the dryer (43) is connected is disposed above the partition member (91). Although not shown, a part of the refrigerant pipe (34) of the refrigerant circuit (20) is provided so as to penetrate from the lower side to the upper side of the partition member (91). The front (downward in FIG. 6) of the dryer (43) is closed by a plate-like lid member (92).

    The electrical component box (81) includes a box part (81b) whose front surface is openable and closable, and a display part (81d) to which a display panel (81c) is attached. Inside the box part (81b), the control board (81a) and some of the components of the controller (80) are housed. The electrical component box (81) is provided at a side position corresponding to the inverter device (82) with the condenser (31) interposed therebetween.

    The outside fan (35) is provided on the reactor device (83) side in the width direction of the outside storage space (S1) (in FIG. 2, the left side with respect to the center in the width direction of the outside storage space (S1)). It has been. Specifically, the external fan (35) corresponds to the central portion in the width direction of the condenser (31) and is provided at a lateral position corresponding to the reactor device (83) with the condenser (31) interposed therebetween. It has been. The external fan (35) is configured to suck air from below and blow it forward.

    The ventilator (90) is provided in a space partitioned by a partition wall (93) provided on the side of the external fan (35). The ventilator (90) has an intake port (90a) and an exhaust port (90b) to ventilate the container chamber. Specifically, when the concentration of ethylene gas, etc. generated in the chamber exceeds a predetermined level, the intake port (90a) and the exhaust port (90b) are opened at the same time, and the outside air enters the chamber from the intake port (90a). On the other hand, the internal air is discharged from the exhaust port (90b) to clean the internal air.

-Driving action-
Next, the cooling operation of the container refrigeration apparatus (10) will be described.

    First, during a normal cooling operation, the first on-off valve (47) and the third on-off valve (53) are closed, and the second on-off valve (49) is open. In this state, the refrigerant discharged from the compressor (30) dissipates heat to the outside air in the condenser (31) and condenses, and then is decompressed by the main expansion valve (32). And the refrigerant | coolant after pressure reduction absorbs heat from the air in a store | warehouse | chamber by an evaporator (33), and returns to a compressor (30). This refrigerant circulation is repeated (see FIG. 1).

    On the other hand, in the supercooling bypass channel (23), when the first on-off valve (47) is opened, a part of the high-pressure liquid refrigerant condensed by the condenser (31) branches off and flows into the supercooling expansion valve ( After the pressure is reduced in 48), the liquid refrigerant flowing into the secondary side passage (46) of the plate heat exchanger (44) and flowing through the primary side passage (45) is supercooled. The liquid refrigerant supercooled in the primary passage (45) flows to the evaporator (33), while the refrigerant flowing in the secondary passage (46) is in an intermediate pressure state of the compressor (30). Flows into the compression chamber. With this supercooling bypass (23), the liquid refrigerant becomes supercooled and the cooling capacity of the evaporator (33) is improved, and the refrigerant in the secondary passage (46) becomes the intermediate pressure of the compressor (30). By flowing into the compression chamber in the state, the refrigerant circulation amount is improved.

    In the warehouse, the internal fan (36) guides the air in the container body (1) into the internal storage space (S2) and dissipates heat to the refrigerant when passing through the evaporator (33). Cooled. The cooled air flows out into the air passage (S3) and is sent again into the container body (1). As described above, the inside air of the container (1) is refrigerated or frozen by circulating the inside air while cooling.

    On the other hand, outside the warehouse, the outside air is guided to the inflow side space (S11) of the outside storage space (S1) by the outside fan (35) and absorbs heat from the refrigerant when passing through the condenser (31). Heated. The heated refrigerant is discharged to the outside from the outflow side space (S12).

    The outside air led to the inflow side space (S11) of the outside storage space (S1) by the outside fan (35) is a heat-generating component (power) that generates heat before passing through the condenser (31). The inverter (82) having the element (82c) and the reactor (83a)) and the reactor (83) are cooled.

    The power element (82c) generating heat at a high temperature of the inverter device (82) radiates heat to the inverter box (82b), and the inverter box (82b) radiates heat to the outside air flowing toward the condenser (31). To be cooled.

    The power element (82c) radiates heat to the inverter box (82b), and the inverter box (82b) radiates heat to the high-pressure liquid refrigerant flowing in the two refrigerant pipes (34) via the cooler (42). It is also cooled by doing. The power element (82c) also radiates heat to the casing body (2) via the inverter box (82b), and the casing body (2) is also cooled by radiating heat to outside air.

    On the other hand, the reactor (83a) that generates heat at a high temperature in the reactor device (83) radiates heat from the front surface of the reactor (83a) to the reactor cover (83b) and the radiation fin (83d), and the reactor cover (83b) and the radiation fin (83d) is cooled by releasing heat to the outside air flowing toward the condenser (31).

    The reactor (83a) radiates heat from the front surface of the reactor (83a) to the casing body (2) via the reactor cover (83b), or radiates heat from the rear surface of the reactor (83a) to the casing body (2). The casing body (2) is also cooled by dissipating heat to the outside air.

    When the evaporator (33) is frosted, a defrosting operation is performed to open the third on-off valve (53) and close the main expansion valve (32). During this defrost operation, the high-temperature refrigerant gas discharged from the compressor (30) is supplied to the evaporator (33), and the frost in the evaporator (33) is removed. At this time, the discharge pressure adjustment valve (38) is opened at the minimum opening, and the refrigerant is supplied to the cooler (42) side by an amount necessary for cooling the power element (82c) of the inverter device (82). Shed.

-Effect of the embodiment-
According to the container refrigeration apparatus (10), the inverter device (82) having the heat generating components (power element (82c), reactor (83a)) and the reactor apparatus (83) are heat-source side heat exchange according to the present invention. The inverter (82) and the reactor device (83) are installed in a location where they can be sufficiently cooled by being arranged on the upstream side (inflow side space (S11)) of the air flow of the condenser (31), which is a condenser. be able to. In addition, by installing the relatively heavy reactor device (83) on the opposite side of the installation side of the heavy compressor (30) with respect to the center in the width direction of the external storage space (S1), The weight balance is improved. That is, according to the container refrigeration apparatus (10), the inverter apparatus (82) and the reactor apparatus (83) can be sufficiently cooled, and an arrangement configuration having an excellent overall weight balance can be realized.

    Further, according to the container refrigeration apparatus (10), the inverter (82) is stored in the warehouse by attaching the cooler (42) through which the high-pressure liquid refrigerant of the refrigerant circuit (20) flows to the inverter apparatus (82). It can be cooled not only by the outside air but also by the refrigerant flowing through the refrigerant circuit (20). For this reason, the inverter device (82) has a relatively low heat-resistant temperature as compared with the reactor device (83). However, the inverter device (82) can prevent a failure by sufficiently cooling it.

    Further, according to the container refrigeration apparatus (10), the inverter apparatus (82) is provided between the compressor (30) and the reactor apparatus (83), so that the inverter apparatus (82) is connected to the refrigerant circuit (20). Therefore, the cooler (42) can be easily installed. That is, when the inverter device (82) is arranged at a position far from the compressor (30), the refrigerant pipe is used to cool the inverter device (82) by the cooler (42) provided in the refrigerant circuit (20). Although it is necessary to extend (34) toward the inverter device (82), the refrigerant pipe (34) is unnecessarily extended by installing the inverter device (82) near the refrigerant circuit (20) as described above. The cooler (42) can be easily installed without doing so.

    Further, in the container refrigeration apparatus (10), the external fan (35) is provided at a side position corresponding to the reactor apparatus (83) with the condenser (31) in the inflow side space (S11) interposed therebetween, and the reactor apparatus Since the heat dissipating fins (83d) are provided in (83), the reactor device (83) can be effectively cooled by being disposed at a location where the air flow of the external fan (35) is relatively high. By arranging as described above, the external fan (35) is arranged on the reactor device (83) side having a weight smaller than that of the compressor (30) in the width direction, so the compressor (30) side in the width direction. Load can be reduced, and the weight balance can be further improved.

    Further, according to the container refrigeration apparatus (10), the inverter device (82) having the heat generating components (power element (82c), reactor (83a)) and the reactor device (83) are arranged below the condenser (31). Therefore, the inverter device (82) and the reactor device (83) can be effectively cooled by the air flowing into the condenser (31). In addition, by forming the width of the condenser (31) shorter than the width of the external storage space (S1) and arranging the condenser (31) so as not to reach the upper side of the compressor (30), the width It is possible to further improve the weight balance by reducing the load on the compressor (30) side with respect to the direction.

<Other embodiments>
In addition, the refrigerant circuit which the container refrigeration apparatus which concerns on this invention has is not restricted to the refrigerant circuit (20) of the said embodiment. For example, the circuit may be capable of reverse cycle defrost by reversibly circulating the refrigerant.

    Further, the inverter device (82) may be provided not on the compressor (30) and the reactor device (83) but on the opposite side of the compressor (30) with the reactor device (83) interposed therebetween. Even in such a case, the inverter device (82) and the reactor device (83) can be sufficiently cooled, and an arrangement configuration having an excellent overall weight balance can be realized.

    Furthermore, the inflow side space (S11) and the outflow side space (S12) are not partitioned by the condenser (31) and the partition member (91) constituting the heat source side heat exchanger according to the present invention, but are condensed. It may be partitioned only by the vessel (31). That is, the length in the width direction of the condenser (31) may be formed to be substantially equal to the width of the external storage space (S1).

    In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

    As described above, the present invention is useful for the arrangement of components of a container refrigeration apparatus.

1 Container body
2 Casing body (compartment member)
4 Casing
10 Container refrigeration equipment
20 Refrigerant circuit
30 Compressor
31 Condenser (heat source side heat exchanger)
34 Refrigerant piping
35 Outside fan
42 Cooler
82 Inverter device
83 Reactor device
83d Heat dissipation fin
91 Partition member
S1 Outer storage space
S2 Storage space in the warehouse
S11 Inflow side space
S12 Outflow side space

Claims (4)

A casing (4) having a partition member (2) that is attached to the opening end face of the container body (1) and divides the storage space (S1) and the storage space (S2), and the storage space ( A compressor (30) provided in S1) and a refrigerant circuit (20) having a heat source side heat exchanger (31) provided in the external storage space (S1) and exchanging heat between the external air and the refrigerant; A container refrigeration apparatus that cools the interior of the container,
An inverter device (82) for controlling the rotational speed of the compressor (30);
A reactor device (83) for suppressing a reverse phase current in the power circuit of the compressor (30),
In the central part in the vertical direction of the external storage space (S1), an air inflow side space (S11) is formed below, while an air outflow side space (S12) is formed above. A heat source side heat exchanger (31) is provided,
The compressor (30), the inverter device (82), and the reactor device (83) are provided in the inflow side space (S11), and the compressor (30) and the reactor device (83) A container refrigeration apparatus, wherein the container refrigeration apparatus is disposed on one side and the other side with respect to the center in the width direction of the external storage space (S1). In claim 1,
A cooler (42) that is provided in the refrigerant circuit (20) and cools the inverter device (82) by the refrigerant flowing through the refrigerant circuit (20);
The container refrigeration apparatus, wherein the inverter device (82) is disposed between the compressor (30) and the reactor device (83). In claim 1 or 2,
An external fan (35) for forming an air flow passing through the heat source side heat exchanger (31),
The outside fan (35) is provided in the outflow side space (S12), and is provided at a side position corresponding to the reactor device (83) with the heat source side heat exchanger (31) interposed therebetween,
The container apparatus (83) includes a heat dissipating fin (83d). In any one of Claims 1 thru | or 3,
The outside storage space (S1) includes the heat source side heat exchanger (31) and a partition member (91) provided on one end side in the width direction of the heat source side heat exchanger (31). Partitioned into a space (S11) and the outflow side space (S12),
The inverter device (82) and the reactor device (83) are disposed below the heat source side heat exchanger (31), while the compressor (30) is disposed below the partition member (91). A container refrigeration apparatus characterized by comprising:

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