JP2014129982A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve a capability of cooling electric components.SOLUTION: In an air conditioner (1), an evaporator (34) and a fan (35) are accommodated in a cooling chamber (21) in a casing (10), and the fan (35) is configured to attract air in the cooling chamber (21). In the air conditioner (1), the cooling chamber (21) communicates with an interior of an electric component box (50) and the interior of the electric component box (50) communicates with an exterior thereof so that the air passes through the interior of the electric component box (50) and flows to the cooling chamber (21) in response to the attraction of the air by the fan (35).

Description

    The present invention relates to an internal / external air conditioner that cools a room, and particularly relates to a measure for improving the ability to cool electrical components.

    2. Description of the Related Art Conventionally, an internal / external integrated air conditioner that cools a room is known. For example, the air conditioner disclosed in Patent Document 1 includes a casing, a refrigerant circuit in which a compressor, a condenser, an expansion valve, and an evaporator are connected in order, and a fan. The inside of the casing is partitioned into a machine room and a cooling room, a compressor, a condenser, and an expansion valve are housed in the machine room, and an evaporator and a fan are housed in the cooling room. In this air conditioner, when the fan is driven, outdoor air is sent to the cooling chamber via the duct and flows into the evaporator. In the evaporator, the outdoor air and the refrigerant exchange heat, and the refrigerant evaporates to cool the outdoor air. And the air cooled with the evaporator is sent to a room | chamber interior via a duct from a cooling room, and a room | chamber interior is cooled.

JP 2008-8543 A

    In the conventional air conditioner, as shown in FIG. 5, an electrical component box (50) containing an electrical component (60) such as a power module for driving a compressor is usually attached to the outer surface of the casing (10). ing. The electrical component box (50) has an inlet (51) at the bottom and an outlet (52) at the top. In the electrical component box (50), when the electrical component (60) generates heat, the air around the electrical component (60) rises in temperature and natural convection is generated upward. And by this natural convection, air flows in from an inflow port (51), and flows out from an outflow port (52), thereby cooling the electrical component (60).

    However, in the conventional air conditioner, since the inflow amount of air into the electrical component box (50) by natural convection is small, the ability to cool the electrical component (60) is low, and the electrical component (60) is sufficiently cooled. It was difficult.

    This invention is made | formed in view of such a problem, The objective is to improve the capability to cool the electrical component in an electrical component box.

    The first invention includes a refrigerant circuit (30) in which a compressor (31), a condenser (32), and an evaporator (34) are sequentially connected to perform a refrigeration cycle, the compressor (31), and the condenser A casing having a machine chamber (22) in which (32) is accommodated and a cooling chamber (21) in which the evaporator (34) is accommodated and in which air is cooled by the evaporator (34). (10), a fan (35) that is accommodated in the cooling chamber (21), sucks air in the cooling chamber (21) and blows it outside, and is attached to the outer surface of the casing (10), and the compressor The air conditioner (1) including the electrical component box (50) in which the electrical component (60) for driving (31) and the fan (35) is built is intended. The electrical component box (50) has a communication port (71) that communicates with the outside, and a communication path (73) that communicates the interior of the electrical component box (50) with the cooling chamber (21). Is provided.

    In the first aspect of the invention, when the fan (35) in the cooling chamber (21) is driven, the fan (35) sucks the air in the cooling chamber (21) and blows it out, so that the cooling chamber (21) The inside becomes negative pressure. Then, due to the negative pressure, air flows from the outside into the electrical component box (50) through the communication port (71), and from the electrical component box (50) through the communication path (73) to the cooling chamber ( 21). The electrical component (60) is cooled by releasing heat to the air in the electrical component box (50).

    In a second aspect based on the first aspect, the communication path (73) opens at an upper portion of the electrical component box (50).

    In the second aspect of the invention, the opening of the communication passage (73) through which air flows out is provided in the upper part of the electrical component box (50). Therefore, air of relatively high temperature heated by the electrical component (60) and rising in the electrical component box (50) preferentially flows out into the cooling chamber (21) via the communication path (73).

    In a third aspect based on the second aspect, the communication port (71) is provided on the lower surface of the electrical component box (50).

    In the third aspect of the invention, air flows in from the communication port (71) on the lower surface of the electrical component box (50) and flows from the bottom to the top in the electrical component box (50). It flows out to the communication passage (73) opening at the top.

    According to a fourth invention, in any one of the first to third inventions, the communication path (73) is formed by a resin tube (74).

    In the fourth aspect of the invention, the communication path (73) is formed by a resin tube (74) having a low heat transfer coefficient. Therefore, it is difficult for the cooling heat in the cooling chamber (21) to be transmitted into the electrical component box (50) via the tube (74), and as a result, condensation in the electrical component box (50) is suppressed.

    In a fifth aspect based on the fourth aspect, the tube (74) is provided such that the opening end on the cooling chamber (21) side faces downward.

    In the fifth aspect of the invention, the open end of the tube (74) on the cooling chamber (21) side faces downward. Therefore, even if the condensed water in the cooling chamber (21) adheres to the tube (74), the situation where the condensed water flows from the opening end of the tube (74) and flows into the electrical component box (50) is avoided. The

    According to the present invention, the outside and the inside of the electrical component box (50) are communicated, and the interior of the electrical component box (50) and the cooling chamber (21) are further communicated. As a result, the suction of the fan (35) of the cooling chamber (21) allows air to flow from the outside through the electrical component box (50) to the cooling chamber (21). The electrical component (60) in) can be cooled. As a result, the amount of air flowing into the electrical component box (50) is increased compared to the conventional case where natural electrical convection is generated in the electrical component box (50) to cool the electrical component (60). The ability to cool the part (60) can be improved.

    According to the second invention, the opening of the communication path (73) through which air flows out is provided in the upper part of the electrical component box (50). As a result, the relatively high temperature air heated by the electrical component (60) can be discharged to the cooling chamber (21) without accumulating in the upper part of the electrical component box (50), and cooling of the electrical component (60) Efficiency can be improved.

    According to the third aspect of the invention, the communication port (71) through which air flows is provided on the lower surface of the electrical component box (50). Thereby, in the electrical component box (50), air can flow smoothly from bottom to top, and the cooling efficiency of the electrical component (60) can be further improved.

    According to the fourth invention, the communication path (73) is formed by the resin tube (74) having a low heat transfer coefficient. This makes it difficult to transfer the cold heat in the cooling chamber (21) into the electrical component box (50) via the tube (74), and can suppress condensation in the electrical component box (50). A short circuit of the electrical component (60) due to water can be prevented more reliably.

    According to the fifth invention, the open end of the tube (74) on the cooling chamber (21) side is directed downward. This prevents the condensed water in the cooling chamber (21) from adhering to the tube (74) from flowing into the electrical component box (50) from the open end of the tube. It is possible to more reliably prevent electrical components from being short-circuited due to the intrusion of condensed water.

FIG. 1 is a schematic configuration diagram of an air conditioner according to an embodiment. FIG. 2 is a diagram showing a state in which the casing panel is removed in FIG. 1. FIG. 3 is a schematic cross-sectional view of the air conditioner according to the embodiment. FIG. 4 is a piping system diagram of the air conditioner according to the embodiment. FIG. 5 is an enlarged cross-sectional view of a portion where an electrical component box is attached in a conventional air conditioner.

    Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

    The air conditioner (1) according to the embodiment of the present invention is placed on, for example, a ship deck, sucks and cools outdoor air, and supplies the cooled air to the room (chamber). As shown in FIGS. 1 and 2, the air conditioner (1) includes a casing (10), a compressor unit (31), a condenser (32), an expansion valve (33) (not shown), and evaporation. Device (34) and a fan (35).

    The casing (10) is formed in a substantially rectangular parallelepiped shape, and includes a base (11), a frame (12) assembled on the base (11), and a panel (40) attached to the frame (12). ).

    As shown in FIG. 3, the rear panel (40a) has a suction port (16) that extends over the entire surface, and outdoor air is passed through the suction port (16) into the air conditioner (1). A suction duct (18) for suction is connected. The upper panel (40b) has an air outlet (17) near the center. The air outlet (17) is supplied with air cooled by the air conditioner (1). The air duct (19) is connected.

    The interior of the casing (10) is partitioned vertically by a partition plate (20). Specifically, a cooling chamber (21) having the suction port (16) and the blower outlet (17) is formed above the partition plate (20), and a machine chamber (22) is formed below. Is formed. An evaporator (34) and a fan (35) are arranged in the cooling chamber (21), and a compressor unit (31), a condenser (32), and an expansion valve (33) ( (Not shown). Moreover, the heat insulating material (23) is affixed on the inner surface of each panel (40) in the cooling chamber (21).

    As shown in FIG. 4, the compressor unit (31), the condenser (32), the expansion valve (33), and the evaporator (34) are sequentially connected by piping, and the refrigerant circulates to refrigeration cycle. A refrigerant circuit (30) for performing the above is formed.

    The compressor unit (31) compresses the refrigerant in the refrigerant circuit (30), and includes four compressors (31a to 31d). These four compressors (31a to 31d) are so-called hermetic scroll compressors, and connected in parallel to each other, the discharge side is connected to the condenser (32), and the suction side is the evaporator (34). )It is connected to the. Note that the number of compressors (31a to 31d) in the compressor unit (31) is merely an example, and is not limited thereto.

    The condenser (32) is a so-called shell-and-tube type water heat exchanger, and is configured such that the supplied water (for example, seawater) and the refrigerant exchange heat to condense the refrigerant. Yes.

    The expansion valve (33) is an electronic expansion valve with a variable opening.

    The evaporator (34) is a so-called cross fin type fin-and-tube heat exchanger, and in the cooling chamber (21), the rear panel (40a) covers the suction port (16). It is attached. The evaporator (34) is configured such that the outdoor air sucked from the suction port (16) and the refrigerant exchange heat, and the refrigerant evaporates while the outdoor air is cooled.

    As shown in FIG. 3, the fan (35) is a double-suction multiblade type blower that sucks outdoor air from the suction duct (18) into the cooling chamber (21) and flows into the evaporator (34). The air cooled by the evaporator (34) is sent into the room (chamber) via the air supply duct (19). The fan (35) includes a fan casing (35a) and an impeller (35b).

    The fan casing (35a) is formed in a substantially spiral shape, and has a suction port (35c) at the center and a blower outlet (35d) at the top. The air inlet (35c) of the fan casing (35a) opens into the cooling chamber (21), and the air outlet (35d) of the fan casing (35a) is connected to the air outlet (17) of the casing (10). .

    The impeller (35b) is accommodated in the fan casing (35a). The impeller (35b) has a rotating shaft connected to a fan motor (37) via a belt (36), and is configured to rotate by driving the fan motor (37) (see FIG. 2). ).

<Electrical component box>
As shown in FIG. 3, the electrical component box (50) is attached to the casing (10) on the outer surface of the front panel (40a). The electrical component box (50) is a vertically long rectangular parallelepiped and includes the electrical component (60).

    The electrical component (60) is a component for driving the compressor (31a-31d) and the fan (35), such as a power module that supplies power to the compressor (31a-31d), and the electrical component (60) It is attached to the inner substrate (61). Specifically, the substrate (61) is disposed in the electrical component box (50) near the rear surface and substantially parallel to the rear surface, and the electrical component (60) is attached to the front surface of the substrate (61). Yes.

<Air cooling passage>
In the air conditioner (1) of the present embodiment, an air cooling passage (70) is provided to cool the electrical component (60) in the electrical component box (50) with air. The air cooling passage (70) includes an inlet (71), a heat radiation passage (72), and a communication passage (73).

    The inflow port (71) allows the outside to communicate with the inside of the electrical component box (50) and allows air to flow into the electrical component box (50) from the outside, and constitutes the communication port of the present invention. Yes. The inflow port (71) is formed on the lower surface of the electrical component box (50).

    The heat radiation path (72) is an air passage for radiating heat from the electrical component (60) to the air. The heat dissipation path (72) is formed between the substrate (61) to which the electrical component (60) is attached and the rear surface of the electrical component box (50) in the electrical component box (50), and extends in the vertical direction. ing. The lower end of the heat radiation path (72) is generally opposed to the inflow port (71).

    The communication path (73) communicates the interior of the electrical component box (50) with the cooling chamber (21). The communication path (73) is formed by a resin tube (74). This tube (74) is inserted into insertion holes formed in the upper part of the front panel (40c) and the upper part of the rear surface of the electrical component box (50), respectively, and one end opens into the electrical component box (50). The other end opens into the cooling chamber (21). In the electrical component box (50), the tube (74) is inserted into the upper end of the heat dissipation path (72) from above, and the open end thereof faces downward. On the other hand, in the cooling chamber (21), the tube (74) is fixed to the frame (38) supporting the fan (35) in a state of extending long downward to the vicinity of the partition plate (20), and its open end faces downward. It has become.

-Driving action-
Next, the operation of the air conditioner (1) will be described.

    As shown in FIG. 4, when the compressors (31a to 31d) of the compressor unit (31) are started, the refrigerant flows in the direction of the arrow, and the high-temperature and high-pressure refrigerant compressed by the compressors (31a to 31d) is condensed. Flow into vessel (32).

    In the condenser (32), the refrigerant condenses by exchanging heat with supplied water (for example, seawater). And the condensed refrigerant | coolant is sent to an expansion valve (33) from a condenser (32), and is pressure-reduced, and flows in into an evaporator (34) after that.

    In the evaporator (34), the refrigerant exchanges heat with the outdoor air flowing into the cooling chamber (21) from the suction duct (18), and the refrigerant absorbs heat and evaporates, while the outdoor air is cooled. The evaporated refrigerant is sent from the evaporator (34) to the compressors (31a to 31d) of the compressor unit (31), and is compressed again in the compressors (31a to 31d). On the other hand, the cooled outdoor air is sent from the cooling chamber (21) to the room (chamber) via the air supply duct (19) by the fan (35) in the cooling chamber (21). ) Is cooled.

    By the way, in the air conditioner (1), the electric component (60) in the electric component box (50) generates heat during the operation. Therefore, it is necessary to cool the electrical component (60) to prevent thermal runaway.

    However, in the present embodiment, the electrical component (60) is cooled by the air flowing through the air cooling passage (70) during operation. Specifically, when the fan (35) in the cooling chamber (21) is driven, the fan (35) sucks the air in the cooling chamber (21) and blows it out. Negative pressure. Then, due to the negative pressure, air flows from the outside into the electrical component box (50) through the inlet (71), and in the electrical component box (50), the air passes through the heat dissipation path (72) from below. After that, it flows out from the upper end of the heat radiation path (72) through the communication path (73) to the cooling chamber (21). The electrical component (60) in the electrical component box (50) is cooled by releasing heat to the air passing through the heat dissipation path (72).

-Effect of the embodiment-
In this embodiment, the outside and the inside of the electrical component box (50) are communicated by the inflow port (71), and further, the interior of the electrical component box (50) and the cooling chamber (21) are communicated by the communication path (73). Was made to communicate. As a result, the suction of the fan (35) of the cooling chamber (21) allows air to flow from the outside through the electrical component box (50) to the cooling chamber (21). The electrical component (60) in) can be cooled. As a result, the amount of air flowing into the electrical component box (50) is increased compared to the conventional case where natural electrical convection is generated in the electrical component box (50) to cool the electrical component (60). The ability to cool the part (60) can be improved.

    Moreover, in this embodiment, the opening connected to the exterior is not formed in the upper surface of an electrical component box (50). Therefore, it is possible to prevent a situation in which water (for example, condensed water) enters from the opening on the upper surface and falls down to the electrical component (60), and as a result, the electrical component (60) is short-circuited.

    In the present embodiment, the opening of the communication path (73) (tube (74)) through which air flows out is provided in the upper part of the electrical component box (50). As a result, the relatively high temperature air heated by the electrical component (60) can be discharged to the cooling chamber (21) without accumulating in the upper part of the electrical component box (50), and cooling of the electrical component (60) Efficiency can be improved.

    In the present embodiment, the communication port (71) through which air flows is provided on the lower surface of the electrical component box (50). Thereby, in the electrical component box (50), air can flow smoothly from bottom to top, and the cooling efficiency of the electrical component (60) can be further improved.

    In the present embodiment, the communication path (73) is formed by a resin tube (74) having a low heat transfer coefficient. This makes it difficult to transfer the cold heat in the cooling chamber (21) into the electrical component box (50) via the tube (74), and can suppress condensation in the electrical component box (50). A short circuit of the electrical component (60) due to water can be prevented more reliably.

    Further, in the present embodiment, the tube (74) is extended long downward in the cooling chamber (21), and the opening end is directed downward as it is. This prevents the condensed water in the cooling chamber (21) from adhering to the tube (74) from flowing into the electrical component box (50) from the open end of the tube. It is possible to more reliably prevent electrical components from being short-circuited due to the intrusion of condensed water.

<< Other Embodiments >>
In the above embodiment, the inlet (71) of the air cooling passage (70) is formed on the lower surface of the electrical component box (50), but it is formed at a place other than the upper surface of the electrical component box (50). I just need it. Further, the number and shape of the inflow ports (71) are not limited to this.

    In the above embodiment, the heat radiation path (72) of the air cooling passage (70) is formed in the electrical component box (50) on the rear surface side of the substrate (61) to which the electrical component (60) is attached. However, the heat radiation path (72) may be formed on the front side of the substrate (61), or may be formed on both the front side and the rear side of the substrate (61).

    In the embodiment, the communication path (73) of the air cooling path (70) is formed by the resin tube (74). However, the communication path (73) may have any form and material as long as it communicates the interior of the electrical component box (50) and the cooling chamber (21).

    The present invention is useful for an air conditioner that includes a refrigerant circuit and a fan and supplies cooled air to the room.

1 Air Conditioner 10 Casing 21 Cooling Chamber 22 Machine Chamber 30 Refrigerant Circuit 31 Compressor (Compressor Unit)
32 Condenser 34 Evaporator 35 Fan 50 Electrical component box 60 Electrical component 71 Inlet (communication port)
73 Communication passage 74 Tube

Claims (5)

A refrigerant circuit (30) in which a compressor (31), a condenser (32), and an evaporator (34) are connected in order to perform a refrigeration cycle;
A machine chamber (22) in which the compressor (31) and the condenser (32) are accommodated, and a cooling chamber in which the evaporator (34) is accommodated and in which air is cooled by the evaporator (34) ( 21) and a casing (10) formed inside;
A fan (35) housed in the cooling chamber (21), sucking air in the cooling chamber (21) and blowing it out;
The air conditioner includes an electrical component box (50) that is attached to the outer surface of the casing (10) and that houses electrical components (60) that drive the compressor (31) and the fan (35). And
The electrical component box (50) is provided with a communication port (71) communicating with the outside, and a communication passage (73) communicating the interior of the electrical component box (50) with the cooling chamber (21). An air conditioner characterized by having In claim 1,
The air-conditioning apparatus, wherein the communication path (73) opens at an upper portion of the electrical component box (50). In claim 2,
The air conditioner, wherein the communication port (71) is provided on a lower surface of the electrical component box (50). In any one of Claims 1 thru | or 3,
The air-conditioning apparatus, wherein the communication path (73) is formed by a resin tube (74). In claim 4,
The air conditioner characterized in that the tube (74) is provided such that the opening end on the cooling chamber (21) side faces downward.

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