RU2560344C2 - External unit of cooling device - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: present invention relates to the external unit of the cooling device, in particular to the design of the electric unit. The external unit contains a housing with a side surface with an inlet hole for air, a blower above an inlet hole and a heat exchanger, note that the blower includes a fan and a bell. The electric unit is located in the housing from the transversal side of a bell, while the unit contains the inlet section formed in the side surface opposite to the side surface facing towards the bell which is interconnected with the outlet side of the blower. The air channel is formed between the top surface of the electric unit and the top panel of the housing with a possibility of air intake from the output side of the blower into the inlet section.

EFFECT: invention allows to provide more space for the blower located in the top part of the housing.

9 cl, 18 dwg

Description

Technical field

The present invention relates to an outdoor unit of a cooling device. In particular, the present invention relates to the construction of an electrical component unit.

BACKGROUND OF THE INVENTION

Disconnected air conditioning devices, each including an indoor unit and an outdoor unit, are traditionally widely used. In the outdoor unit, electrical components, such as a blower and compressor, are housed in the housing, and an electrical component unit is provided in which electrical components, such as a control board, adapted to control said electrical elements are placed.

During operation of the air conditioning device, an electrical component (s) located in an electrical component unit generates heat. Such heat generation can increase the temperature of the gaseous medium inside the block of the electrical component, leading, for example, to damage to the electrical component (s). Therefore, as described in Patent Document 1, the electrical component (s) are cooled to form an opening or slit in the side surface of the electrical component unit located inside the housing to provide a ventilation duct within the electrical component unit.

In Patent Document 1, a blower is placed on the upper side inside the housing, and an electrical component unit is placed under the blower.

List of links

Patent document

Patent Document 1: Unexamined Japanese Patent Application No. 2007-218534

SUMMARY OF THE INVENTION

Technical problem

However, in the above-described patent document 1, elements such as a heat exchanger and compressor and pipes are located on the lower side inside the housing. That is, a heat exchanger, a compressor, pipes and an electrical component unit are located under the blower in the housing. Therefore, the interior of the housing on the lower side relative to the blower is narrowed. Thus, the maintenance of elements placed under the blower cannot be carried out without disconnecting the electrical component unit from the housing.

The present invention has been made in view of the foregoing, and an object of the present invention is to provide more significant space under the blower in a housing in which the blower is located on the upper side.

Solution

A first aspect of the invention is for an outdoor unit of a cooling device including a housing (20) comprising a side surface formed with an air inlet (25); a blower (40) located above the air inlet (25) in the housing (20) and adapted to discharge upward air; and an external heat exchanger (30) located so as to face the air inlet (25). The blower (40) includes a fan (41) and a socket (43) located so as to surround the outer periphery of the fan (41), and an electric component unit (60) located on the periphery of the socket (43) is installed in the housing (20) .

In a first aspect of the invention, an air inlet (25) is formed on a side surface of the housing (20). In the housing (20), the external heat exchanger (30) is located so as to face the air inlet (25). In addition, in the housing (20), the blower (40) is located above the air inlet (25). The blower (40) includes a fan (41) and a bell (43). The bell (43) is located so as to surround the outer periphery of the fan (41).

The air received in the housing (20) through the air inlet (25), through the rotation of the fan (41) exchanges heat in the external heat exchanger (30). Then air passes through the bell (43) and is discharged outside the housing (20).

In the housing (20), the electric component unit (60) is located at the periphery of the socket (43). Thus, the interior of the housing (20) under the fan (41) and the bell (43) is expanded.

The second aspect of the invention is the outdoor unit of the first aspect of the invention, in which the electrical component unit (60) is mounted so that at least a portion of the electrical component unit (60) overlaps with the socket (43) in the height direction, and the lower end portion of the unit (60) the electrical component is located above the external heat exchanger (30).

In a second aspect of the invention, the electric component unit (60) is mounted so that at least a portion of the electric component unit (60) overlaps with the socket (43) in the height direction. In addition, the electric component unit (60) is mounted so that its lower end portion is located above the external heat exchanger (30).

A third aspect of the invention is an outdoor unit of the first or second aspect of the invention, in which the electrical component unit (60) includes an inlet portion (61) that communicates with an outlet side of the blower (40) and through which air on said outlet side enters the unit ( 60) of the electrical component, and an outlet portion (62) that communicates with the inlet side of the blower (40) and through which air is discharged inside the block (60) of the electrical component.

In a third aspect of the invention, an inlet portion (61) communicating with an outlet side of the blower (40) and an outlet portion (62) communicating with an inlet side of the blower (40) are provided in the electric component unit (60). Air on the inlet side of the blower (40) enters the electric component unit (60) through the inlet portion (61). Then, the received air is discharged from the electric component unit (60) to the inlet side of the blower (40) through the outlet section (62).

When air is ejected from the blower (40), the air pressure at the inlet side of the blower (40) in the housing (20) is a pressure (i.e., negative pressure) below atmospheric pressure. On the other hand, the air pressure at the outlet side of the blower (40) is a pressure (i.e., positive pressure) above atmospheric pressure.

Due to the pressure difference between the air on the outlet side of the blower (40) and the air on the inlet side of the blower (40), the air on the outlet side of the blower (40) enters the electric component unit (60) through its inlet section (61). The received air passes through the inside of the electric component unit (60) and then exits to the inlet side of the blower (40) through the outlet section (62).

A fourth aspect of the invention is for an outdoor unit of any one of the first to third aspects of the invention, in which in the housing (20) a backup (20a, 20d) adapted to support the lower part of the electric component unit (60) is provided between the first chamber (2b), which is formed on the upper side inside the housing (20) and in which the blower (40) and the electric component unit (60) are placed, and a second chamber (2a), which is formed on the lower side inside the housing (20) and in which the external heat exchanger ( thirty).

In a fourth aspect of the invention, a first chamber (2b) on the upper side and a second chamber (2a) below the first chamber (2b) are formed in the housing (20). A blower (40) and an electric component unit (60) are placed in the first chamber (2b). An external heat exchanger (30) is placed in the second chamber (2a). In the housing (20) between the first chamber (2b) and the second chamber (2a), a backup (20a, 20d) is provided. The support (20a, 20d) supports the lower part of the block (60) of the electrical component.

The fifth aspect of the invention is an outdoor unit of the fourth aspect of the invention, in which an outlet section (62) is formed in the lower part of the block (60) of the electrical component, and an air channel (28) is formed in the support (20a, 20d) to direct the air leaving through the outlet section (62) into the second chamber (2a).

In a fifth aspect of the invention, an outlet portion (62) is formed at the bottom of the block (60) of the electrical component. In addition, an air channel (28) is formed in the backup (20a, 20d).

When the blower (40) drives air, the air pressure in the second chamber (2a) of the housing (20) is a pressure (i.e., negative pressure) below atmospheric pressure. On the other hand, the air pressure at the outlet side of the blower (40) is a pressure (i.e., positive pressure) above atmospheric pressure.

Due to the pressure difference between the air in the first chamber (2b) and the air in the second chamber (2a), the air in the first chamber (2b) of the housing (20) enters the electric component unit (60) through its inlet section (61). The received air passes through the inner side of the block (60) of the electrical component and then exits through the exhaust section (62). The discharged air enters the second chamber (2a) of the housing (20) through the air channel (28) formed in the backup (20a, 20d).

The sixth aspect of the invention is for an outdoor unit of the fourth aspect of the invention, in which a hole (29) for a wire is formed in the support (20a, 20d) through which an electric wire extends from the electric component unit (60).

In a sixth aspect of the invention, a wire hole (29) is formed in the backup (20a, 20d). The hole (29) for the wire allows you to pass through it an electric wire emerging from the block (60) of the electrical component.

The seventh aspect of the invention is for the outdoor unit of the fifth or sixth aspect of the invention, in which the outlet portion (62) of the electric component unit (60) and the air channel (28) of the support (20a, 20d) are arranged so as to be offset from each other in the horizontal direction .

In a seventh aspect of the invention, the outlet portion (62) of the electric component unit (60) and the air channel (28) of the support (20a, 20d) are arranged so as to be offset from each other in the horizontal direction. That is, when viewed from above, the openings of the outlet section (62) and the air channel (28) do not overlap with each other. For example, even if moisture in the second chamber (2a) enters the first chamber (2b) through the air channel (28), it is unlikely that moisture will reach the inside of the electric component unit (60) through the outlet section (62) due to displacement of the outlet section (62) ) and the air channel (28) in the horizontal direction.

An eighth aspect of the invention is for an outdoor unit of any of the fourth to seventh aspects of the invention, wherein the electrical component unit (60) is removable outside the housing (20), and the external shape of the electrical component unit (60) is a narrowed shape in which the electric component unit (60) tapers from the front side to the rear side in the extraction direction.

In an eighth aspect of the invention, the electric component unit (60) is arranged to be retrieved outside the housing (20). In addition, the external shape of the electric component unit (60) is such a narrowed shape that the electric component unit (60) tapers from the front side to the rear side in the extraction direction. Thus, the block (60) of the electrical component can be easily pulled out of the housing (20).

The ninth aspect of the invention is for an outdoor unit of any of the fourth to eighth aspects of the invention, in which the electric component unit (60) is formed so that its surface facing inward is located along the outer periphery of the socket (43).

In a ninth aspect of the invention, the inwardly facing surface of the electric component unit (60) is formed along the outer periphery of the socket (43). Thus, the block (60) of the electrical component can be easily placed on the periphery of the socket (43).

Advantages of the Invention

In the first and second aspects of the invention, the block (60) of the electrical component is located on the periphery of the socket (43) to expand the space under the socket (43). Thus, the maintenance of the elements located under the socket (43) in the housing (20) can be carried out without disconnecting the block (60) of the electrical component from the housing (20).

Elements, such as a compressor (5a), can be placed under the socket (43) in the housing (20). Thus, it is possible to reduce the size of the outdoor unit of the cooling device in the height direction.

According to a third aspect of the invention, since the outlet portion (62) communicating with the inlet side of the blower (40) and the inlet portion (61) communicating with the outlet side of the blower (40) can be enlarged in the electric component block (60), the pressure difference between the air at the inlet of the inlet section (61) of the electric component unit (60) and the air at the outlet of the outlet section (62) of the electric component block (60). This increases the volume of air moving inside the block (60) of the electrical component. As a result, the electrical component (s) in the block (60) of the electrical component can be sufficiently cooled.

According to a fourth aspect of the invention, since a backup (20a, 20d) is provided, it is possible to provide support for the lower part of the electric component unit (60). Thus, the block (60) of the electrical component can be firmly fixed in the housing (20).

According to a fifth aspect of the invention, since an outlet portion (62) is formed in the lower part of the block (60) of the electrical component, and an air channel (28) is formed in the backup (20a, 20d), air leaving the outlet portion (62) of the block ( 60) of the electrical component, can be directed into the second chamber (2a) of the housing (20) through the air channel (28).

According to a sixth aspect of the invention, since a hole (29) for the wire is formed, the electric wire exiting from the electric component unit (60) can be pulled to the second chamber (2a). Thus, the electric component (s) of the element (s) located under the blower (40) in the housing (20) can be connected to the block (60) of the electric component by means of said wire.

According to a seventh aspect of the invention, since the outlet portion (62) of the electric component unit (60) and the air channel (28) of the support (20a, 20d) are arranged so that the openings of the outlet section (62) and the air channel (28) do not overlap on the other hand, when viewed from above, it is unlikely that moisture will reach the inside of the electric component unit (60), even if moisture passes from the second chamber (2a) into the first chamber (2b) through the air channel (28).

According to an eighth aspect of the invention, since the electric component unit (60) is removable outside the housing (20) and is so constricted that the electric component unit (60) tapers from the front side to the rear side in the extraction direction, (60) the electrical component can be easily removed from the housing (20). Thus, the maintainability of the electric component unit (60) can be improved.

According to a ninth aspect of the invention, since the electric component unit (60) is configured so that its inward surface is located along the outer periphery of the socket (43), the electric component unit (60) can be easily placed on the periphery of the socket (43). Elements, such as a compressor, can be placed under the socket (43) in the housing (20). Thus, it is possible to reduce the size of the outdoor unit of the cooling device.

Brief Description of the Drawings

FIG. 1 is a perspective view of an outdoor unit of a first embodiment.

FIG. 2 is a perspective view of an outdoor unit of a first embodiment in which some details are omitted.

FIG. 3 is a perspective view of an outdoor unit of a first embodiment in which some details are omitted.

FIG. 4 is a schematic sectional view of an electric component unit of a first embodiment.

FIG. 5 is a perspective view of an electrical component unit of a first embodiment in which some details are omitted.

FIG. 6 is a perspective view of an outdoor unit of a second embodiment.

FIG. 7 is a perspective view of an outdoor unit of a second embodiment in which some details are omitted.

FIG. 8 is a perspective view of an outdoor unit of a second embodiment in which some details are omitted.

FIG. 9 is a schematic sectional view of a block of an electrical component of a second embodiment.

FIG. 10 is a perspective view of an electrical component unit of a second embodiment in which some details are omitted.

FIG. 11 is a side view of an electrical component unit of a first embodiment in which some parts are omitted.

FIG. 12 is a perspective view of an electrical component unit of a second embodiment in which some details are omitted.

FIG. 13 is a right side view of an outdoor unit of a third embodiment.

FIG. 14 is a view of an internal structure of an electric component unit of a third embodiment.

FIG. 15 is a perspective view of an electrical component unit of a third embodiment.

FIG. 16 is a perspective view of an electric component unit of a third embodiment from beneath an electric component unit.

FIG. 17 is a front view of an electrical component unit of a third embodiment.

FIG. 18 is a view showing air flow in an outdoor unit of a third embodiment.

Description of Embodiments

Embodiments of the present invention will be described in detail below with reference to the drawings.

First Embodiment

Referring to FIG. 1-3, the outdoor unit (10) of the first embodiment is used for an air conditioning device, which is a cooling device. Although not shown, the indoor unit is connected to the outdoor unit (10) to carry out a vapor compression refrigeration cycle.

The outdoor unit (10) is placed, for example, on the roof of the building. The outdoor unit (10) includes a housing (20), an external heat exchanger (30), outdoor fans (40) and a compression mechanism (50).

The housing (20) is made in a rectangular shape when viewed from above. The housing (20) includes four supports (21), a lower frame (22), side panels (23) and an upper panel (24).

Supports (21) are provided respectively in the four corners of the housing (20), and the lower frame (22) is attached to the lower parts of the supports (21).

Side panels (23) include upper panels (23a) forming the upper half of the housing (20) on its four sides, a front panel (23b) forming the left half of the front surface of the housing (20) in its lower half, and a transverse side panel (23c), forming the front half of the left side surface of the housing (20) in its lower half. On the sides of the housing (20), the inlets (25) are respectively formed in the right half of the front surface of the housing (20) in its lower half, the right side surface of the housing (20) in its lower half of the rear surface of the housing (20) in its lower half and rear half of the left side surface of the housing (20) in its left half. The inlet (25) serves as the air inlet of the present invention.

The upper panel (24) is attached to the upper ends of the supports (21), and outlet openings (26) are formed on the upper surface (24). The upper panel (24) includes grilles (24a), each covering one of the respective outlet openings (26).

The external heat exchanger (30) is a heat exchanger of finned tubes and is adapted to exchange heat between the outside air and the refrigerant. The external heat exchanger (30) is provided in a vertical position and is made in the form of a curved heat exchanger extending along all side surfaces of the housing (20). Between the lateral edges of the external heat exchanger (30), predetermined openings (3a) are formed in order to insert a front left corner of the housing (20). That is, in the housing (20), the front panel (23b) and the transverse side panel (23c) are respectively connected to the openings (3a) of the external heat exchanger (30).

The compression mechanism (50), the oil separator (51) and the accumulator (52) are attached to the lower frame (22), and the compression mechanism (50) includes two compressors (5a, 5b).

In the housing (20), horizontally extending front strut (20a), horizontally extending lateral struts (20b, 20d) and horizontally extending rear strut (20c) are located between the lower chamber (2a), in which the external heat exchanger (30) is located, and the upper chamber (2b), in which external fans (40) are housed, and attached to four sides of the housing (20). It is noted that the front strut (20a) will be described below. The upper chamber (2b) serves as the first chamber of the present invention, and the lower chamber (2a) serves as the second chamber of the present invention.

The pressure of the air moving on the exhaust side of the outdoor fan (40) in the upper chamber (2b) is a pressure (i.e., positive pressure) above atmospheric pressure. On the other hand, the lower chamber (2a) is a chamber where air moves on the inlet side of the outdoor fan (40). The pressure of air moving through the lower chamber (2a) is a pressure (i.e., negative pressure) below atmospheric pressure.

Outdoor fans (40) include two outdoor fans (40). Each outdoor fan (40) includes a fan working part (41), which is a blade fan, a fan motor (not shown in the drawing) and a bell (43). The working part (41) of the fan and the fan motor are attached to the front support (20a) and the rear support (20c). It is noted that the outdoor fan (40) serves as the blower of the present invention. In addition, the working part (41) of the fan serves as a fan of the present invention.

The bell (43) includes a working part (44) made in the form of a cylinder, and a base (45) made essentially in the form of a rectangular plate, when viewed from above.

The base (45), on its four outer peripheral sides, is attached to the props (20a-20d). In the center of the base (45), an air passage opening is formed having substantially the same diameter as the diameter of the main part (44).

The block (60) of the electrical component, in which, for example, an electrical component adapted to control the compression mechanism (50) and others, is mounted, is attached to the housing (20).

An electric component unit (60) is located above the front of the external heat exchanger (30) near the upper end of the external heat exchanger (30). In addition, an electric component unit (60) is provided between the upper panel (23a) and each of the sockets (43) of the outdoor fans (40). In addition, the electric component unit (60) is mounted so that the lower end part of the electric component unit (60) is located above the external heat exchanger (30) and the part of the electric component unit (60) overlaps with the sockets (43) in the height direction. It is noted that the electric component unit (60) serves as the electric component unit of the present invention.

Specifically, the electric component unit (60), referring to FIG. 2 and 4, is a box made in the form of a substantially rectangular flat plate, and is attached to the housing (20) in such a way that the electric component unit (60) is supported from above by the front strut (20a). Although not shown in the drawing, legs are respectively provided at the four corners of the lower part of the electric component unit (60), and the lower part of the electric component unit (60) is located a short distance from the surface of the front support (20a).

On the rear surface of the block (60) of the electrical component, a protrusion (64) protruding backward. Inside the protrusion (64) is placed the reactor (71), which is an element that generates heat. In addition, in the block (60) of the electrical component is placed, for example, a control board (70) adapted to control compressors (5a, 5b), etc.

An inlet portion (61) is formed in the electric component block (60), through which air is drawn into the electric component block (60), and an exhaust section (62) through which air is discharged outside the electric component block (60).

Holes are formed in the inlet portion (61), and the inlet portion (61) is formed on the rear surface of the electric component unit (60). The inlet portion (61) allows the inner chamber of the electric component unit (60) and part of the upper chamber (2b) on the outlet side of the outdoor fan (40) to communicate with each other.

Specifically, the following are formed in the inlet portion (61) as shown in FIG. 4 and 5, slots (65) formed in the essentially lower part of the protrusion (64) on the rear surface of the electric component unit (60), and an opening (66) formed in the lower part of the casing wall of the electric component unit (60) on its rear surface. Slots (65) serve as the inlet of the inlet portion (61), and the hole (66) serves as the outlet of the inlet portion (61). Thus, the inlet portion (61) may have a labyrinth structure. Therefore, you can be sure that rainwater entering the body (20) cannot penetrate the electric component unit (60).

Holes are formed in the outlet portion (62), and the outlet portion (62) is formed near the first end of the electric component unit (60) in its longitudinal direction at the bottom of the electric component unit (60). The outlet section (62) opens into the interior of the block (60) of the electrical component, and also opens onto the front strut (20a). It is noted that the side adjacent to the first end of the electric component unit (60) in its longitudinal direction is the side close to the right when viewed from the front in FIG. 1, and the side adjacent to the second end of the electric component unit (60) in its longitudinal direction is the side close to the left when viewed from the front in FIG. one.

The front support (20a) is attached to the front side of the housing (20) and serves as a support of the present invention. The front strut (20a) is made in the form of a substantially rectangular flat plate when viewed from above. The front support (20a), in both its end sections, is attached to two supports (21) located in the width direction of the housing (20) on its front side and is fixed in a horizontal position. A front support (20a), a guide (27), a cutout (29) and slots (28) are formed.

The guide (27) is used to place the block (60) of the electrical component relative to the outer side surface of the socket (43). A guide (27) protrudes upward from the upper surface of the front strut (20a) and is formed near the rear end portion of the front strut (20a) on its upper surface in the longitudinal direction of the front strut (20a).

The cutout (29) is adapted to guide the wire (s) of the bundle (s) leaving the inside of the block (60) of the electrical component to the lower chamber (2a) and to direct the refrigerant pipe (s) to the lower chamber (2a) and serves as wire holes of the present invention. The cutout (29) is formed in such a way that a substantially rectangular part of the front end portion of the front strut (20a) on the side adjacent to the second end of the block (60) of the electrical component in its longitudinal direction, when viewed from above, is cut out. It is noted that said refrigerant pipe is formed as a pipe through which refrigerant moves and is adapted to cool, for example, a heat sink and a control board (70) located inside the electrical component unit (60) in contact with it.

Each of the slots (28) is an opening through which air exiting through the outlet portion (72) of the electric component unit (60) is directed to the lower chamber (2a) and serves as the air channel of the present invention. Slots (28) are formed in the front end portion of the front strut (20a) on a side adjacent to the front end of the electric component unit (60) in its longitudinal direction. The slots (28) and the outlet section (62) of the electric component unit (60) are arranged so that the holes of the slots (28) and the holes of the outlet section (62) do not overlap when viewed from above. That is, the slots (28) and the outlet section (62) of the electric component unit (60) are formed so that the holes of the slots (28) and the holes of the outlet section (62) are offset from each other in the horizontal direction. Thus, moisture passing from the lower chamber (2a) to the upper portion of the front strut (20a) through slots (28) cannot penetrate into the electric component unit (60) through the outlet section (62).

As described above, the inner part of the housing (20) is divided into the upper chamber (2b) and the lower chamber (2a) by means of supports (20a-20d), sockets (43) and the electric component unit (60). Thus, in the housing (20), the upper chamber (2b) is formed with positive pressure, and the lower chamber (2a) is formed with negative pressure.

Airflow in outdoor unit during operation

During operation of the outdoor unit (10), the outdoor fans (40) are driven to force air from the outside of the housing (20) through the inlets (25) and the outdoor heat exchanger (30), and then air is sucked into the lower chamber ( 2a). Passing through the external heat exchanger (30), the intake air exchanges heat with the refrigerant flowing through the external heat exchanger (30). Air moving through the lower chamber (2a) passes upward and enters the upper chamber (2b). Then the air is sucked into the external fans (40) and then discharged through the outlet openings (26).

Airflow in electrical unit

During operation of the outdoor unit (10), the outdoor fans (40) are also driven to generate airflow inside the electrical component unit (60).

Specifically, the actuation of external fans (40), referring to FIG. 4 and 5, causes the air pressure on the exhaust side of the outdoor fan (40) in the upper chamber (2b) to become positive pressure above atmospheric pressure, and on the other hand, the air pressure in the lower chamber (2a) becomes negative pressure below atmospheric pressure.

Due to the pressure difference between the air at the inlet of the inlet section (61) of the electric component unit (60) and the air at the outlet of the outlet section (62) of the electric component unit (60), the air on the outlet side of the outdoor fan (40) moves into the protrusion (64) through the slots (65) inlet section (61). After air passes through the protrusion (64) and cools the reactor (71), the air passes into the casing of the block (60) of the electrical component through the hole (66). Moving downward, the air passing into the body of the block (60) of the electric component cools the control board (70) and other components provided in the block (60) of the electric component. Then, the air passing through the electric component block (60) leaves the electric component block (60) through the outlet section (62) of the lower part of the electric component block (60).

Then, part of the air leaving the block (60) of the electrical component through the outlet section (62) is moved to the lower chamber (2a) through the notch (29) of the front support (20a), and the remaining part of the air passes into the lower chamber (2a) through cracks (28).

The air leaving the lower chamber (2a) is sucked into the outdoor fans (40). Then the air moves up and is released outside the housing (20).

Advantages of the First Embodiment

According to a first embodiment, the electric component unit (60) is arranged at the periphery of the sockets (43) in order to expand the space under the sockets (43). Thus, the maintenance of elements located under the sockets (43) in the housing (20) can be carried out without disconnecting the block (60) of the electrical component from the housing (20).

Elements, such as a compressor (5a), can be placed under the sockets (43) in the housing (20). Thus, it is possible to reduce the size of the outdoor unit (10) of the cooling device in the height direction.

An optional component (s), such as an active noise filter, can be installed by using the space in the position corresponding to the openings (3a) of the external heat exchanger (30) under the sockets (43) in the housing (20).

Since the outlet section (62) communicating with the inlet side of the external fan (40) and the inlet section (61) communicating with the outlet side of the external fan (40) are formed in the electric component block (60), the pressure difference between the air at the inlet of the inlet section (61) of the electric component unit (60) and the air at the outlet of the outlet portion (62) of the electric component unit (60) can be increased. This increases the volume of air passing through the block (60) of the electrical component. As a result, the control board (70) provided inside the unit (60) of the electrical component can be sufficiently cooled.

Since a front support (20a) is provided, support for the lower portion of the block (60) of the electrical component can be provided. Thus, the block (60) of the electrical component can be firmly fixed in the housing (20).

Since an outlet section (62) is formed in the lower part of the block (60) of the electrical component, and slots (28) are formed in the front support (20a), air moving through the outlet section (62) of the block (60) of the electric component can be directed to the lower chamber (2a) of the housing (20) through the slots (28).

Since a cut-out (29) is formed, the electric wire (s) emerging from the electric component unit (60) can be extended to the lower chamber (2a). Thus, the electric component (s) of the element (s) located under the external fans (40) in the housing (20) can be connected to the block (60) of the electric component by means of said wire (s).

Since the outlet section (62) of the electric component unit (60) and the front support slit (28) (20a) are located so that the holes of the outlet section (62) and the slot openings (28) do not overlap with each other, when viewed from above, it is unlikely that moisture will reach the inside of the electric component unit (60), even if moisture passes from the lower chamber (2a) to the upper chamber (2b) through slots (28).

Second Embodiment

A second embodiment of the present invention will be described below. Referring to FIG. 6-8, the outdoor unit (10) of the second embodiment is used for an air conditioning device, which is a cooling device. Although not shown, the indoor unit is connected to the outdoor unit (10) to carry out a vapor compression refrigeration cycle.

The outdoor unit (10) is placed, for example, on the roof of the building. The outdoor unit (10) includes a housing (20), an external heat exchanger (30), an outdoor fan (40), and a compression mechanism (50).

The housing (20) is made in a rectangular shape when viewed from above. The housing (20) includes four supports (21), a lower frame (22), side panels (23) and an upper panel (24).

The supports (21) are located respectively in the four corners of the housing (20), and the lower frame (22) is attached to the lower parts of the supports (21).

Side panels (23) include upper panels (23a) forming the upper half of the housing (20) on its four sides, a front panel (23b) forming the left half of the front surface of the housing (20) in its lower half, and a transverse side panel (23c), forming the front half of the left side surface of the housing (20) in its lower half. On the sides of the housing (20), the inlets (25) are respectively formed in the right half of the front surface of the housing (20) in its lower half, the right side surface of the housing (20) in its lower half, the rear surface of the housing (20) in its lower half, the rear half of the left side surface of the housing (20) in its lower half.

An upper panel (24) is attached to the upper ends of the supports (21), and an outlet (26) is formed in the upper panel (24). The top panel (24) includes a grill (24a) covering the outlet (26).

The external heat exchanger (30) is a heat exchanger of finned tubes and is adapted to exchange heat between the outside air and the refrigerant. Referring to FIG. 7 and 8, the external heat exchanger (30) is provided in an upright position and is made in the form of a curved heat exchanger extending along all side surfaces of the housing (20). Between the lateral edges of the external heat exchanger (30), predetermined openings (3a) are formed in order to insert a front left corner of the housing (20). That is, in the housing (20), the front panel (23b) and the transverse side panel (23c) are respectively connected to the openings (3a) of the external heat exchanger (30).

The compression mechanism (50), the oil separator (51), and the battery (52) are attached to the lower frame (22), and the compression mechanism (50) includes one compressor (5a).

In the housing (20), a horizontally extending front strut (20a), a horizontally extending right strut (20b), a horizontally extending left strut (20d) and a horizontally extending rear strut (20c) are located between the lower chamber (2a) in which the outdoor heat exchanger ( 30), and the upper chamber (2b), in which the outdoor fan (40) is placed, and attached to the four sides of the housing (20). It is noted that the left support (20d) will be described below. The upper chamber (2b) serves as the first chamber of the present invention, and the lower chamber (2a) serves as the second chamber of the present invention.

The pressure of the air moving on the exhaust side of the outdoor fan (40) in the upper chamber (2b) is a pressure (i.e., positive pressure) above atmospheric pressure. On the other hand, the lower chamber (2a) is a chamber where air moves on the exhaust side of the outdoor fan (40). The pressure of the air moving through the lower chamber (2a) is the pressure (i.e. negative pressure) below atmospheric.

The outdoor fan (40) includes a fan working part (41), which is a blade fan, a fan motor, and a bell (43). The working part (41) of the fan and the fan motor are attached to the front support (20a) and the rear support (20c).

The bell (43) includes the working part (44), made in the form of a cylinder, and the base (45), made in the form of a rectangular plate, when viewed from above.

The base (45), on its four outer peripheral sides, is attached to the props (20a-20d). In the center of the base (45), an opening for passing air is formed, the diameter of which is essentially equal to the diameter of the working part (44).

The block (60) of the electrical component, in which, for example, an electrical component adapted to control the compression mechanism (50) and others, is mounted, is attached to the housing (20). The electric component unit (60) is mounted on the left support (20d) located on the left when viewed from the front of the housing (20), and is also installed near the upper end of the external heat exchanger (30). In addition, an electric component unit (60) is provided between the upper side panel (23a) located on the left when viewed from the front of the housing (20) and the socket (43) of the outdoor fan (40). In addition, the electric component unit (60) is installed so that the lower end part of the electric component unit (60) is located above the external heat exchanger (30), and the part of the electric component unit (60) overlaps with the socket (43) in the height direction.

Referring to FIG. 9-12, the electric component unit (60) is made in the form of an elongated rectangular parallelepiped, and the electric component unit (60) is made so that the area of the first side surface of the electric component unit (60) is larger than the area of the second side surface of the electric unit (60) a component opposite said first side surface. The electric component unit (60) is supported vertically by means of a left support (20d) and is located along the left periphery of the socket (43). Although not shown, legs are respectively provided at the corners of the lower part of the electric component unit (60), and the lower part of the electric component unit (60) is located at a small distance from the upper surface of the left support (20d). In the second embodiment, when the electric component unit (60) is installed in the housing (20), said first side surface is the front surface of the electric component unit (60), and said second side surface is the rear surface (back surface) of the unit (60) ) electrical component.

In the electric component unit (60), a first protrusion (64a) protruding to the right, as seen in FIG. 7 is formed in a part of the electric component unit (60) adjacent to its first side surface, and a second protrusion (64b) is formed protruding back from a part of the electric component unit (60) adjacent to its second side surface. In the first protrusion (64a) is placed the reactor (71), which is an element that generates heat. In addition, in the housing of the block (60) of electronic components is placed, for example, a control board (70) adapted to control the compressor (5a).

On the inwardly facing surface of the block (60) of the electrical component, an arcuate, when viewed in plan, recess is formed along the outer periphery of the socket (43).

An electric component (s), such as a control board (70) adapted to control the compressor (5a), is placed in the electric component unit (60). In addition, in the electric component unit (60), first, second and third inlet sections (61a, 61b, 61c) are provided through which air is introduced into the electric component block (60), and an exhaust section (62) through which air is discharged the limits of the block (60) of the electrical component.

Openings are formed in the first inlet portion (61a), and the first inlet portion (61a) is formed in the interior of the electric component unit (60) near its first side surface. The first inlet portion (61a) allows the interior of the electric component unit (60) and the outlet side of the outdoor fan (40) in the upper chamber (2b) to communicate with each other.

Specifically, the following are formed in the first inlet portion (61a) as shown in FIG. 9 and 10, slots (65) formed in the lower part of the first protrusion (64a) on the side surface of the block (60) of the electrical component; and an opening (66) formed in the upper part of the wall of the side surface of the housing of the block (60) of the electrical component. Slots (65) serve as the input of the first inlet portion (61a), and the hole (66) serves as the output of the first inlet portion (61a). Thus, the first inlet portion (61a) may have a labyrinth structure. Therefore, you can be sure that rainwater entering the body (20) cannot penetrate the electric component unit (60).

Holes are formed in the outlet portion (62), and the outlet portion (62) is formed near the rear end of the electric component unit (60) in its longitudinal direction at the bottom of the electric component unit (60). The outlet portion (62) opens into the interior of the block (60) of the electrical component, and also opens onto the left support (20d).

Openings are formed in the second inlet portion (61b), and the second inlet portion (61b) is formed in a portion of the electric component unit (60) adjacent to its second side surface. The second inlet portion (61b) allows the interior of the electric component unit (60) and the outlet side of the outdoor fan (40) in the upper chamber (2b) to communicate with each other.

Specifically, in the second inlet portion (61b), the following are formed, as shown in FIG. 11 and 12, slots (65) formed in the lower part of the second protrusion (64b) on the second side surface of the electric component unit (60); and an opening (66) formed in a part of the body of the block (60) of the electrical component adjacent to its second side surface. Slots (65) serve as the entrance of the second inlet portion (61b), and the hole (66) serves as the outlet of the second inlet portion (61b). Thus, the second inlet portion (61b) may have a labyrinth structure. Therefore, it can be guaranteed that rainwater entering the body (20) through the outlet (26) cannot penetrate the electric component unit (60).

A plurality of slots are formed in the third inlet portion (61c) and formed in the substantially upper part of the left side surface of the electric component unit (60), as seen in FIG. 7.

The left support (20d) is attached to the left side of the housing (20) and serves as a support of the present invention. The left support (20d) is in the form of a substantially rectangular flat plate when viewed in plan. The left support (20d) is held in a horizontal position so that the end portions of the left support (20d) in its anteroposterior direction are attached to two supports (21), respectively, located on the front left side and the rear left side of the housing (20) . A guide (not shown in the drawing) and a cutout (29) and slots (28) are formed in the left support (20d).

The said guide is used to place the block (60) of the electrical component relative to the outer side surface of the socket (43). The guide extends upward from the upper surface of the left support (20d) and is formed near the left end portion of the left support (20d) on its upper surface in the longitudinal direction of the left support (20d).

The cutout (29) is adapted to guide the wire (s) exiting from the inside of the block (60) of the electrical component into the lower chamber (2a) and to direct the refrigerant pipe (s) to the lower chamber (2a) and serves as an opening for the wire of the present inventions. The cutout (29) is formed in such a way that a substantially rectangular part of the left support (29) is cut out near the front end of the left support (29) in its longitudinal direction, when viewed in plan. It is noted that the refrigerant pipe is formed as a pipe through which the refrigerant flows and is adapted to cool, for example, a heat sink and a control board (70) located inside the electrical component unit (60) in contact with it.

Each of the slots (28) is an opening through which the air leaving the outlet section (62) of the electric component unit (60) is directed to the lower chamber (2a) and serves as the air channel of the present invention. Slots (28) are formed near the rear end portion of the left support (20d) in its longitudinal direction. The slots (28) and the outlet section (62) of the electric component unit (60) are arranged so that the holes of the slots (28) and the holes of the outlet section (62) do not overlap when viewed from above. That is, the slots (28) and the outlet section (62) of the electric component unit (60) are arranged so that the openings of the slots (28) and the holes of the outlet section (62) of the electric component block (60) are offset from each other in the horizontal direction. Thus, moisture penetrating from the lower chamber (2a) into the upper part of the left support (20d) through the slots (28) can be prevented from entering the electric component unit (60) through the outlet section (62).

As described above, the inner part of the housing (20) is divided into an upper chamber (2b) and a lower chamber (2a) by means of props (20a-20d), a bell (43), and an electric component unit (60). Thus, in the housing (20), the upper chamber (2b) is formed with positive pressure, and the lower chamber (2a) is formed with negative pressure.

Method of attachment / detachment of an electrical component unit

A method for attaching / disconnecting the electric component unit (60) to / from the housing (20) will be described. When the electric component unit (60) is attached to the housing (20), the attachment is made in such a way that the electric component unit (60) is pushed from front to back along the left support (20d) in a position in which the upper panel (23a) on the front side is detached.

On the other hand, when the electric component unit (60) is disconnected from the housing (20), the disconnection is carried out in such a way that the electric component unit (60) is pulled back and forth along the left support (20d) to the position in which the upper panel (23a) is front side disconnected.

Airflow in electrical unit

During operation of the outdoor unit (10), the outdoor fan (40) is adapted to generate air flow inside the unit (60) of the electrical component.

Specifically, driving the outdoor fan (40), referring to FIG. 9-12, leads to the fact that the air pressure on the exhaust side of the outdoor fan (40) in the upper chamber (2b) becomes a positive pressure above atmospheric pressure, and, on the other hand, causes the air pressure in the lower chamber (2a ) becomes negative pressure below atmospheric pressure.

Due to the pressure difference between the air at the inlet of the first inlet portion (61a) of the electric component unit (60) and the air at the outlet of the outlet section (62) of the electric component unit (60), the air on the outlet side of the outdoor fan (40) moves to the first protrusion (64a) block (60) of the electrical component through the first inlet portion (61a). After air passes through the first protrusion (64a) and cools the reactor (71), air enters the casing of the block (60) of the electrical component through the hole (66). Moving downward, the air entering the body of the block (60) of the electric component cools the control board (70) and other components provided in the block (60) of the electric component. Then, the air passing through the electric component block (60) leaves the electric component block (60) through the outlet section (62) of the lower part of the electric component block (60).

Due to the pressure difference between the air at the inlet of the second inlet section (61b) and the air at the outlet of the outlet section (62), the air on the outlet side of the outdoor fan (40) moves into the second protrusion (64b) of the electric component unit (60) through the second inlet section (61b) ) After air passes through the second protrusion (64b), air enters the body of the block (60) of the electrical component through the hole (66). Moving downward, the air entering the body of the block (60) of the electric component cools the control board (70) and other components provided in the block (60) of the electric component. Then, the air moving through the electric component block (60) leaves the electric component block (60) through the outlet section (62) of the lower part of the electric component block (60).

Due to the pressure difference between the air at the inlet of the third inlet section (61c) and the air at the outlet of the outlet section (62), the air on the outlet side of the outdoor fan (40) moves into the body of the electric component unit (60) through the third inlet section (61c). Moving downward, the air cools the control board (70) and other components provided in the block (60) of the electrical component. Then, the air passing through the electric component block (60) leaves the electric component block (60) through the outlet section (62) of the lower part of the electric component block (60).

Part of the air moving outside the block (60) of the electric component through the outlet section (62) enters the lower chamber (2a) through the cutout (29) of the left support (20d), and the remaining part of the air passes into the lower chamber (2a) through the slots (28).

The air leaving the lower chamber (2a) is sucked into the outdoor fan (40). Then the air moves up and is released outside the housing (20).

Advantages of the Second Embodiment

According to a second embodiment, since a left support (20d) is provided, support for the lower part of the electric component unit (60) can be provided. Thus, the block (60) of the electrical component can be firmly fixed in the housing (20).

Since an outlet portion (62) is formed in the lower part of the block (60) of the electrical component, and gaps (28) are formed in the left support (20d), the air exiting through the outlet portion (62) of the block (60) of the electrical component can be directed to the lower chamber (2a) of the housing (20) through the slots (28).

Since a cut-out (29) is provided, the electric wire (s) exiting the block (60) of the electric component can be extended to the lower chamber (2a). Thus, the electric component (s) of the element (s) located under the outdoor fan (40) in the housing (20) can be connected to the block (60) of the electric component by means of said wire (s).

Since the outlet section (62) of the block (60) of the electric component and the slots (28) of the left support (20d) are located so that the holes of the outlet section (62) and the holes of the slots (28) do not overlap with each other, when viewed from above, it is unlikely that moisture will reach the inside of the electric component unit (60), even if moisture passes from the lower chamber (2a) to the upper chamber (2b) through slots (28).

Since the electric component unit (60) is removable outside the housing (20) and is narrowed so that the electric component unit (60) tapers from the front to the rear side in the extraction direction, the electric component unit (60) can be easily removed from the housing (20). Thus, the maintainability of the electric component unit (60) can be improved.

Since the electric component unit (60) is designed so that its inwardly facing surface is located along the outer periphery of the socket (43), the electric component unit (60) can be easily placed on the periphery of the socket (43). A space under the bell (43) in the housing (20) can be formed, and thus another element (s) can be placed. Thus, it is possible to reduce the size of the outdoor unit (10) of the cooling device. Other configurations, features and advantages of the second embodiment are similar to the configurations, features and advantages of the first embodiment.

Third Embodiment

A third embodiment of the present invention will be described below. The first and third embodiments differ from each other in the configuration of the electric component unit (60). It is noted that in the third embodiment only differences from the first embodiment will be described, and similar elements are not described again.

Referring to FIG. 13, an electric component unit (60) in which, for example, an electric component adapted to control the compression mechanism (50), etc., is mounted, is attached to the housing (20). An electric component unit (60) is located above the front of the external heat exchanger (30) near the upper end of the external heat exchanger (30). In addition, an electric component unit (60) is provided between the upper side panel (23a) and each of the sockets (43) of the outdoor fans (40). The upper panel (24) of the housing (20) is located directly above the block (60) of the electrical component. In addition, the electric component unit (60) is installed so that the lower end part of the electric component unit (60) is located above the external heat exchanger (30), and the part of the electric component unit (60) overlaps with the sockets (43) in the height direction. Block (60) of the electrical component is made so that its height is greater than the height of the socket (43).

Referring to FIG. 14-16, the electric component unit (60) is a box made in the form of a substantially rectangular flat plate and attached to the housing (20) in a position in which the electric component unit (60) is supported upward by the front strut (20a). Although not shown in the drawing, legs are respectively provided at the four corners of the lower part of the electric component unit (60), and the lower part of the electric component unit (60) is located a short distance from the surface of the front support (20a).

In the block (60) of the electrical component, first and second inlet portions (61a, 61b) are provided through each of which air is let into the electric component block (60), and an outlet section (62) through which air is discharged outside the block (60) electrical component. Specifically, in each of the first and second inlet portions (61a, 61b), a plurality of slots are formed, and the first and second inlet portions (61a, 61b) are formed in the substantially upper part of the front surface of the electric component unit (60), as seen in FIG. 15. The first inlet section (61a) contains slots located in five columns, and is provided on the right side of the block (60) of the electrical component. The second inlet portion (61b) contains slots located in one column, and is provided on the left side of the block (60) of the electrical component.

Holes through each of which air circulates are formed in the outlet section (62) and are formed near the right side (the first end of the electric component block (60) in its longitudinal direction) in the lower part of the electric component block (60). The outlet portion (62) opens into the interior of the electric component unit (60) and opens to the left support (20d) in a position in which the electric component unit (60) is located in the housing (20).

On the upper surface of the block (60) of the electrical component, first to third seals (81, 82, 83) of the end sections and first and second contact elements (84, 85) are provided.

The first and second contact elements (84, 85) are elements each adapted to protect the upper panel (24) and the electric component unit (60) from contacting each other due to, for example, vibration. Each of the first and second contact elements (84, 85) is formed in a substantially U-shape when viewed in cross section. In addition, each of the first and second contact elements (84, 85) includes a housing (86) formed with a substantially rectangular upper surface, and two flanges (87), each extending horizontally, from one of the end parts enclosures (86).

The first contact element (84) is provided near the right side on the upper surface of the block (60) of the electrical component so as to correspond to the area where the first inlet portion (61a) is not provided.

A second contact element (85) is provided near the left side on the upper surface of the electric component unit (60) so as to correspond to an area where the first inlet portion (61a) and the second inlet portion (61b) are not provided.

The first and second contact elements (84, 85) are each located so that the longitudinal direction of the flange (87) corresponds to the width direction of the block (60) of the electrical component. A sealing sheet element (88) formed in a substantially rectangular flat shape is provided on the upper surface of the housing (86) of each of the first and second contact elements (84, 85). The first and second contact elements (84, 85) each contact with the upper panel (24) of the housing (20) so that a sealing sheet element (88) is located between them. Thus, noise (contact noise) caused by direct contact between the upper panel (24) and the electric component unit (60) can be reduced or prevented.

An air channel is formed between the inner surface of the housing (86) of each first and second contact elements (84, 85) and the upper surface of the block (60) of the electrical component. Air on the exhaust side of the outdoor fan (40) passes through said air passage and then passes into the space in front of the electric component unit (60).

The first to third seals (81, 82, 83) of the end portions are each adapted to prevent water from entering the first and second inlet portions (61a, 61b). Each of the first to third seals (81, 82, 83) of the end portions is a sealing part made in a substantially L-shape when viewed in cross section. The first to third seals (81, 82, 83) of the end portions are each provided along the front end portion of the block (60) of the electrical component on its upper surface. Each of the first or third seals (81, 82, 83) of the end sections is adapted to contact the upper panel (24) on its upper surface (one side of an L-shaped).

Specifically, the first seal (81) of the end portion corresponds in size to the part of the electric component unit (60) between the right end part of the electric component unit (60) and the first contact element (84). The second seal (82) of the end portion in size corresponds to the zone in which the first inlet portion (61a) is formed, and is provided directly above the first inlet portion (61a). The third seal (83) of the end portion corresponds in size to the zone in which the second inlet portion (61b) is formed, and is provided directly above the second inlet portion (61b).

For example, in the block (60) of the electrical component is placed a control board (70) adapted to control the compressor (5a).

Airflow in electrical unit

During operation of the outdoor unit (10), the outdoor fans (40) generate airflow inside the unit (60) of the electrical component.

Specifically, the actuation of external fans (40), referring to FIG. 17 and 18, causes the air pressure on the exhaust side of the outdoor fan (40) in the upper chamber (2b) to become a positive pressure above atmospheric pressure and, on the other hand, causes the air pressure in the lower chamber (2a) becomes negative pressure below atmospheric pressure.

Due to the pressure difference between the air at the inlets of the first and second inlet portions (61a, 61b) of the electric component unit (60) and the air at the outlet of the outlet section (62) of the electric component unit, air moves on the outlet side of the outdoor fan (40), referring to in FIG. 15, from the rear side to the front side of the electric component unit (60) through the air channels of the first and second contact elements (84, 85) and the left side of the upper surface of the electric component unit (60). Air moving to the front side of the electric component unit (60) passes along the front surface of the electric component unit (60) and then enters the electric component unit (60) through the first and second inlet portions (61a, 61b). Moving downward, the air entering the electric component unit (60) cools the control board (70) and other components provided in the electric component unit (60). Then, the air passing through the electric component block (60) leaves the electric component block (60) through the outlet section (62) of the lower part of the electric component block (60).

Then, part of the air leaving the block (60) of the electrical component through the outlet section (62) is moved to the lower chamber (2a) through the notch (29) of the front support (20a), and the remaining part of the air passes into the lower chamber (2a) through cracks (28).

The air leaving the lower chamber (2a) is sucked into the outdoor fans (40). Then the air moves up and is released outside the housing (20). Other configurations, features and advantages of the third embodiment are similar to the configurations, features and advantages of the first embodiment.

Another embodiment

The present invention may provide for the following configuration for the first embodiment.

When the electric component unit (60) is attached to the body (20), the electric component unit (60) can be attached from above by sliding movement along the right and left supports (21).

The present invention may include the following configurations for the first to third embodiments.

In the first and third embodiments, the electric component unit (60) is supported upwardly by the front strut (20a). However, the present invention is not limited to such a configuration. An opening may be provided in the front strut (20a), and the electric component unit (60) can be supported by the front strut (20a) so that the lower part of the electric component block (60) is inserted into the aforementioned hole. In this case, the electric component unit (60) is held in a position in which its lower end portion protrudes downward from the front support (20a).

In the second embodiment, the electric component unit (60) is supported upwardly by the left support (20d). However, the present invention is not limited to such a configuration. An opening may be formed in the left support (20d), and the electric component unit (60) may be held by the left support (20d) so that the lower part of the electric component unit (60) is inserted into the aforementioned hole. In this case, the electric component unit (60) is held in a position in which its lower end portion protrudes downward from the left support (20d).

In the first to third embodiments, the inner part of the housing (20) is divided into an upper chamber (2b) and a lower chamber (2a) by means of props (20a-20d), a bell (sockets) (43) and an electric component unit (60). However, the present invention is not limited to such a configuration. The inner part of the housing (20) can be divided into the upper chamber (2b) and the lower chamber (2a) only by means of a bell (s) (43).

In the first to third embodiments, the refrigerant pipe (s) cools, for example, the control board (70) and the heat sink in contact with it. However, the present invention is not limited to such a configuration. The heat sink may be cooled in contact with an electrical component, such as a control board (70).

In the first to third embodiments, the electric component unit (60) is supported upwardly by means of a backup (20a, 20d). However, the present invention is not limited to such a configuration. The block (60) of the electrical component can be attached to the supports (21).

It is noted that the above embodiments are described only as preferred examples per se and are not intended to limit the scope, applications and uses of the invention.

Industrial applicability

As described above, the present invention is suitable for an outdoor unit of a cooling device.

Description of Reference Positions

2a bottom camera

2b Upper chamber

20 Housing

20a front support

20d Left backup

25 inlet

28 Slit

29 neckline

30 External heat exchanger

40 outdoor fan

41 Fan part

43 Bell

60 Block electrical component

61 Inlet section

61a first inlet section

61b second inlet section

62 Graduation

Claims (9)

1. An outdoor unit of a cooling device, comprising: a housing (20) comprising a side surface formed with an air inlet (25);
a blower (40) located above the air inlet (25) in the housing (20) and adapted to move the air up; and
an external heat exchanger (30) located so as to face said air inlet (25),
moreover, the blower (40) includes a fan (41) and a bell (43), configured to surround the outer periphery of the fan (41), and
an electric component unit (60) located on the transverse side of the socket (43) and installed in the housing (20),
wherein the electric component unit (60) comprises an inlet portion (61) that communicates with the outlet side of the blower (40) and through which air on said exhaust side enters the electric component unit (60),
while the inlet portion (61) is formed in the side surface of the block of the electrical component opposite the side surface facing the socket (43),
and an air channel is formed between the upper surface of the electric component unit (60) and the upper panel (24) of the housing (20) with the possibility of introducing air from the outlet side of the blower (40) into the inlet section (61). 2. The outdoor unit according to claim 1, in which
the electric component unit (60) is mounted so that the lower end part of the electric component unit (60) is located above the external heat exchanger (30). 3. The outdoor unit according to claim 1, in which
the electric component unit (60) includes an outlet portion (62) that communicates with the inlet side of the blower (40) and through which air inside the electric component unit (60) is discharged. 4. The outdoor unit according to claim 3, in which
in the housing (20), supports (20a, 20d) adapted to support the lower part of the electric component unit (60) are provided between the first chamber (2b), which is formed on the upper side inside the housing (20) and in which the blower (40) is located and an electric component unit (60) and a second chamber (2a), which is formed on the lower side inside the housing (20) and in which the external heat exchanger (30) is placed. 5. The outdoor unit according to claim 4, in which
an outlet portion (62) is formed at the bottom of the block (60) of the electrical component, and
an air channel (28) is formed in the support (20a, 20d), adapted to direct the air exiting through the outlet section (62) into the second chamber (2a). 6. The outdoor unit according to claim 4, in which
a hole (29) for a wire is formed in the support (20a, 20d) through which an electric wire extends from the electric component unit (60). 7. The outdoor unit according to claim 5, in which
exhaust section (62) of the block (60) of the electrical component
and the air channel (28), the supports (20a, 20d) are arranged so as to be offset from each other in the horizontal direction. 8. The outdoor unit according to claim 4, in which
the electric component unit (60) is removable outside the housing (20), and the external shape of the electric component unit (60) is a narrowed shape, the electric component unit (60) tapering from the front side to the rear side in the extraction direction. 9. The outdoor unit according to claim 4, in which
block (60) of the electrical component is made so that its surface facing inward is located along the outer periphery of the socket (43).

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