JP2024078983A - Electric component box and ventilation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To take measures against intrusion of water falling to an electric component box.

SOLUTION: A body box (110) comprises a first surface (F1), and a first partition plate (115b) for separating the inside of the body box (110) into a storage space (S0) and a first space (S1). Introduction ports (H3 and H6) for introducing air on the outside of the body box (110) into the first surface (F1), and a first opening (H1) for discharging air within the storage space (S0) outward by a fan (140) are formed on a surface except the first surface (F1) of the body box (110). A second opening (H2) is formed on the first partition plate (115b).

SELECTED DRAWING: Figure 5

COPYRIGHT: (C)2024,JPO&INPIT

Description

This disclosure relates to an electrical equipment box and a ventilation device.

There is known a ventilation device that exchanges heat between exhaust indoor air and supply outdoor air (see, for example, Patent Document 1). Such a ventilation device is provided with an electrical equipment box. Inside the electrical equipment box, for example, a drive circuit unit for the supply air fan and a drive circuit unit for the exhaust fan are provided.

JP 2014-178083 A

Depending on the environment in which the ventilation system is installed, it may be exposed to falling water droplets. It is important to take measures to prevent falling water from entering the electrical equipment box of the ventilation system.

The purpose of this disclosure is to prevent water from falling into the electrical equipment box.

A first aspect of the present disclosure includes a heat exchanger including a first heat generating component (120a, 120b), a fan (140), and a main body box (110),
The main body box (110) is
The first page (F1) and
a first partition plate (115b) that divides the inside of the main body box (110) into an accommodation space (S0) that accommodates the first heat generating components (120a, 120b) and the fan (140) and a first space (S1) facing the first surface (F1);
Equipped with
inlets (H3, H6) for introducing air outside the main body box (110) into the first space (S1) and a first opening (H1) for discharging air within the storage space (S0) to the outside by the fan (140) are formed on a surface of the main body box (110) other than the first surface (F1),
The first partition plate (115b) has a second opening (H2).
It is an electrical equipment box.

In the first embodiment, the inlets (H3, H6) are formed on a surface other than the first surface (F1). This configuration makes it possible to prevent falling water from entering the electrical equipment box through the inlets (H3, H6) when the electrical equipment box is positioned with the first surface (F1) facing up.

A second aspect of the present disclosure is the electrical component box of the first aspect,
The main body box (110) is
a plurality of side surfaces (F2, F3) different from the first surface (F1) extending in a vertical direction when the main body box (110) is installed;
a second partition plate (115a) that divides the inside of the main body box (110) into the storage space (S0) and a second space (S2) facing at least a part of the plurality of side surfaces (F2, F3);
Equipped with
The first space (S1) and the second space (S2) are in communication with each other,
The inlet (H3, H6) is formed in at least a part of the plurality of side surfaces (F2, F3) constituting the second space (S2).
It is an electrical equipment box.

In the second embodiment, air outside the electrical equipment box is taken into the interior of the electrical equipment box through the second space (S2). In this embodiment, the inlets (H3, H6) are formed on the side surfaces (F2, F3), so that the inlet ports (H3, H6) can be prevented from falling into the electrical equipment box.

A third aspect of the present disclosure is the electrical component box of the second aspect,
A second heat generating component (130b) and a heat sink (130a),
The heat sink (130a) dissipates heat from the second heat generating component (130b) to the second space (S2).
It is an electrical equipment box.

In the third embodiment, the second heat-generating component (130b) dissipates heat to the air via the heat sink (130a). In this embodiment, the heat sink (130a) can be efficiently cooled by the air flow in the second space (S2).

A fourth aspect of the present disclosure is the electrical component box of the third aspect,
a third partition plate (116) that divides the accommodation space (S0) into a first area (A1) in which the first heat generating component (120a, 120b) is accommodated and a second area (A2) in which the second heat generating component (130b) is accommodated;
The second opening (H2) opens into the first region (A1),
The fan (140) is provided in the first area (A1).
It is an electrical equipment box.

In the fourth aspect, an area is divided into an area in which electronic components to be cooled by air from the fan (140) are arranged and an area in which electronic components to be cooled by the heat sink (130a) are arranged. In this aspect, this division allows the cooling air to be efficiently introduced into the first area (A1). As a result, in this aspect, the heat-generating components (120a, 120b, 130b) can be efficiently cooled.

The fifth aspect of the present disclosure is a ventilation device equipped with an electrical equipment box according to any one of the first to fourth aspects.

In the fifth aspect, the ventilation device can achieve the effects based on the electrical component box (100) of any of the first to fourth aspects.

FIG. 1 shows a schematic configuration of a ventilation device. FIG. 2 is a perspective view of the electrical component box. FIG. 3 is a perspective view that illustrates a schematic structure of the storage section. FIG. 4 is a perspective view of the top cover. FIG. 5 is a vertical cross-sectional view showing a schematic internal structure of the main body box. FIG. 6 is a perspective view of the rear cover. FIG. 7 is a perspective view of the lower cover. FIG. 8 is a side view of the inverter circuit board. FIG. 9 is a schematic diagram showing a cross-sectional structure of an electrical component box according to the second embodiment. FIG. 10 is a perspective view illustrating a structure of an upper cover according to the second embodiment. FIG. 11 is a schematic diagram showing a cross-sectional structure of an electrical component box according to the third embodiment.

First Embodiment
A ventilation device (20) will be described as a first embodiment. The ventilation device (20) is intended to ventilate an indoor space. The ventilation device (20) is installed, for example, above the ceiling.

Figure 1 shows a schematic configuration of the ventilation device (20). Figure 1 shows the ventilation device (20) as seen from above. In the example of Figure 1, the ventilation device (20) is installed above the ceiling. An inspection hatch (200) is formed in the ceiling.

The ventilation device (20) includes a casing (21), an intake fan (31), an exhaust fan (32), a total heat exchanger (33), and an electrical equipment box (100).

The casing (21) is formed in a hollow box shape. The casing (21) is formed with an outside air port (22), an exhaust port (23), an inside air port (24), and an air supply port (25). The outside air port (22) and the exhaust port (23) each communicate with an outdoor space via a duct. The inside air port (24) and the air supply port (25) each communicate with an indoor space via a duct.

An air supply passage (26) and an exhaust passage (27) are formed inside the casing (21). The air supply passage (26) is formed from the outside air port (22) to the air supply port (25). The exhaust passage (27) is formed from the inside air port (24) to the exhaust port (23). An air supply fan (31) is arranged in the air supply passage (26). An exhaust fan (32) is arranged in the exhaust passage (27).

The supply air fan (31) and the exhaust fan (32) are, for example, centrifugal fans. The supply air fan (31) and the exhaust fan (32) are configured so that their respective air volumes can be varied. The air volumes can be varied by supplying power to the supply air fan (31) and the exhaust fan (32) via an inverter circuit (described below).

The total heat exchanger (33) is disposed so as to straddle the air supply passage (26) and the exhaust passage (27). The total heat exchanger (33) has a first passage (34) connected to the air supply passage (26) and a second passage (35) connected to the exhaust passage (27). The total heat exchanger (33) exchanges sensible heat and latent heat between the first air flowing through the first passage (34) and the second air flowing through the second passage (35).

A service port (21a) is formed on the side of the casing (21) of the ventilation device (20). When the ventilation device (20) is in operation, the service port (21a) is closed with a lid (21b).

The inspection hatch (200) shown in FIG. 1 is an opening provided in the ceiling of a building. A worker can enter the inspection hatch (200). The worker can access the service hatch (21a) from the inspection hatch (200). In other words, the worker can access the ventilation system (20) from the service hatch (21a) to perform various maintenance tasks.

As shown in FIG. 1, the electrical equipment box (100) is attached to the surface of the casing (21) on which the service port (21a) is provided (the side surface of the ventilation device (20)). The electrical equipment box (100) is adjacent to the service port (21a) of the casing (21).

Figure 2 is a perspective view of the electrical equipment box (100). Figure 2 shows the electrical equipment box (100) with the service port cover (114) (described below) removed. The electrical equipment box (100) includes a main body box (110), a converter circuit board (120), two inverter circuit boards (130), and a fan (140). For ease of explanation, the up-down direction of the electrical equipment box (100) will be defined based on the state shown in Figure 2 below.

<Main unit box (110)>
The main body box (110) is made of a metal such as iron and has a box shape. The main body box (110) includes a rear cover (111), a top cover (112), a bottom cover (113), a service port cover (114), and a storage section (115).

- Storage section (115) -
Fig. 3 is a perspective view that illustrates a schematic structure of the storage section (115). As illustrated in Fig. 3, the storage section (115) is a box-shaped member that is open on two adjacent sides. The two open sides function as service ports.

As shown in FIG. 2, a partition plate (116) (also referred to as a third partition plate) is provided in the space inside the storage section (115) (hereinafter referred to as the storage space (S0)). The partition plate (116) is a plate-shaped member.

In this example, the partition plate (116) extends in the vertical direction when the electrical component box (100) is installed. The partition plate (116) divides the storage space (S0) into a first area (A1) and a second area (A2) (see FIG. 2). In this example, the partition plate (116) is provided so as to divide a portion of the storage space (S0). More specifically, the partition plate (116) is provided adjacent to two inverter circuit boards (130) (described in detail below) that are arranged side by side.

An opening (hereinafter, the second opening (H2)) is formed in the top plate (115b) (also referred to as the first partition plate) of the storage section (115). The second opening (H2) is connected to the first area (A1). Burring is applied to the periphery of the second opening (H2). Specifically, a rise is formed on the periphery of the second opening (H2) that points upward in the storage section (115) (see FIG. 3).

An opening (hereinafter, the fourth opening (H4)) is formed in the bottom plate (115c) of the storage section (115). Burring is applied to the periphery of the fourth opening (H4). Specifically, a rise is formed on the periphery of the fourth opening (H4) that faces downward of the storage section (115). The fourth opening (H4) is connected to the first region (A1). The fourth opening (H4) is also connected to the third space (S3) described below.

The rear plate (115a) (also called the second partition plate) of the storage section (115) has two openings (hereinafter, each of which is named the fifth opening (H5)) (see FIG. 3). These fifth openings (H5) are aligned vertically.

- Service port cover (114) -
The service port cover (114) is a lid for closing the service port (see FIG. 1). The service port cover (114) is a plate-like member having an L-shaped cross section. A worker performing maintenance on the ventilation device (20) can access the inside of the main body box (110) (more specifically, the inside of the storage section (115)) by removing the service port cover (114).

- Top cover (112) -
Fig. 4 is a perspective view of the top cover (112) (also called the second cover). The top cover (112) is a box-shaped member with one side open. In Fig. 4, the lower side of the top cover (112) (the side not visible in Fig. 4) is the open side.

The top cover (112) is attached to the top plate (115b) of the storage section (115) with its open surface facing the top plate (115b). Most of the open surface of the top cover (112) (described below) is covered by the top plate (115b). In FIG. 2, the surface of the top cover (112) that is the top surface of the main body box (110) is designated as the first surface (F1).

Figure 5 is a vertical cross-sectional view showing a schematic internal structure of the main box (110). Figure 5 is a view of the inside of the first area (A1) from the second area (A2) side. As shown in Figure 5, in the main box (110), a space (called the first space (S1)) is formed between the top plate (115b) of the storage section (115) and the top cover (112). The first space (S1) faces the first surface (F1).

- Rear cover (111) -
FIG. 6 is a perspective view of the rear cover (111) (also referred to as the first cover). The rear cover (111) is a box-shaped member with two open sides. The rear cover (111) is attached to the rear plate (115a) of the storage section (115) with one open side facing the rear plate (115a). Most of the open side of the rear cover (111) is covered by the rear plate (115a). The other open side of the rear cover (111) is the upper side when the rear cover (111) is attached to the rear plate (115a). In this example, the upper part of the open side of the rear cover (111) is not covered by the rear plate (115a).

The outer surface of the rear cover (111), which faces the rear plate (115a) of the storage section (115), is named the second surface (F2) (see FIG. 5). In this example, the second surface (F2) extends vertically when the electrical component box (100) is installed. The second surface (F2) may be inclined so that the upper portion protrudes outward more than the lower portion. The second surface (F2) may be formed by utilizing the side surface of the casing (21) of the ventilation device (20).

In the main body box (110), a space (hereinafter referred to as the second space (S2)) is formed between the rear plate (115a) of the storage section (115) and the rear cover (111) (see FIG. 5). The rear cover (111) and the top cover (112) are connected so that the second space (S2) and the first space (S1) are connected.

In this example, the top cover (112) has a portion (hereinafter referred to as a protrusion) that protrudes from the top plate (115b) toward the rear cover (111) (see FIG. 5). The open surface of the top cover (112) that corresponds to the protrusion is not covered by the top plate (115b).

In the electrical component box (100), the protruding portion of the top cover (112) and the upper portion of the rear cover (111) are overlapped so that the open surface corresponding to the protruding portion of the top cover (112) is connected to the open surface of the rear cover (111) that is not covered by the rear plate (115a). When the open surface corresponding to the protruding portion of the top cover (112) is connected to the open surface of the rear cover (111) that is not covered by the rear plate (115a), the second space (S2) and the first space (S1) are connected.

The rear cover (111) has multiple side surfaces (F3) (also called third surfaces) that extend in the vertical direction when the rear cover (111) is attached to the storage section (115). In this example, the side surfaces (F3) extend vertically when the electrical component box (100) is installed. The side surfaces (F3) may be inclined at an angle so that the upper portions are more outward than the lower portions.

As described above, the main box (110) has multiple side surfaces (F2, F3) different from the first surface (F1) that extend in the vertical direction when the main box (110) is installed. The second space (S2) is a space facing at least a portion of the multiple side surfaces (F2, F3).

In this example, the third surface (F3) is a surface perpendicular to the second surface (F2). In the rear cover (111), at least one of the third surfaces (F3) is formed with a plurality of slit-shaped inlets (hereinafter also referred to as third openings (H3)) (see FIG. 6).

Specifically, these third openings (H3) are provided toward the lower side of the third surface (F3). As a result, the third openings (H3) are provided at a position away from the second openings (H2). By providing the third openings (H3) at a position away from the second openings (H2), the electrical component box (100) can more reliably prevent water and dust from entering the storage space (S0).

- Bottom cover (113) -
7 is a perspective view of the bottom cover (113) (also referred to as the third cover). The bottom cover (113) is a box-shaped member with one open side. The bottom cover (113) is attached to the bottom plate (115c) of the storage section (115) with the open side facing the bottom plate (115c) of the storage section (115). The entire open side of the bottom cover (113) is covered by the bottom plate (115c).

In the main box (110), a space (hereinafter referred to as the third space (S3)) is formed between the bottom plate (115c) of the storage section (115) and the bottom cover (113) (see FIG. 5). Here, the surface of the bottom cover (113) that is the bottommost surface of the main box (110) in FIG. 2 is named the fourth surface (F4) (see FIGS. 5 and 7).

The bottom cover (113) has a side surface (F5) (also called the fifth surface) that extends in the vertical direction when the bottom cover (113) is attached to the storage section (115) (see FIG. 7).

In this example, the side surface (F5) extends vertically when the electrical component box (100) is installed. The side surface (F5) of the bottom cover (113) has multiple slit-shaped openings (hereinafter referred to as first openings (H1)).

<Converter circuit board (120)>
In the electrical component box (100), one converter circuit board (120) is disposed in the first area (A1) (see FIG. 2). A converter circuit is mounted on the converter circuit board (120). The converter circuit converts AC voltage into DC voltage and supplies the DC voltage to two inverter circuit boards (130).

The converter circuit includes a capacitor (120a) and a diode bridge circuit (120b) (see FIG. 2). These electronic components are heat-generating components that generate heat during operation of the converter circuit (hereinafter referred to as first heat-generating components (120a, 120b)).

<Inverter circuit board (130)>
8 is a side view of the inverter circuit boards (130). An inverter circuit is mounted on each of the inverter circuit boards (130). The inverter circuit of one inverter circuit board (130) supplies power to the air supply fan (31). The inverter circuit of the other inverter circuit board (130) supplies power to the exhaust fan (32).

These inverter circuit boards (130) are arranged in the second area (A2). The two inverter circuit boards (130) are arranged vertically in the second area (A2).

Each inverter circuit is equipped with an IPM (Intelligent Power Module). An IPM contains an IGBT (Insulated Gate Bipolar Transistor) and other components. The IPM generates heat while the inverter circuit is in operation. Below, the IPM may be referred to as the second heat-generating component (130b).

Each IPM (second heat-generating component (130b)) has a heat dissipation surface that dissipates heat from the IGBTs and the like. A heat sink (130a) is attached to the heat dissipation surface of each IPM (see Figure 8).

The heat sink (130a) has heat dissipation fins. The heat dissipation fins of the heat sink (130a) protrude from the fifth opening (H5) (see FIG. 3) into the second space (S2) (see FIG. 8). The heat dissipation fins dissipate heat from the IPM (second heat-generating component (130b)) to the air in the second space (S2).

<Fan (140)>
The fan (140) is disposed in the first area (A1). More specifically, the fan (140) is disposed below the lower end of the converter circuit board (120) and at a position facing the fourth opening (H4) (see FIGS. 2 and 5). The fan (140) sends air from the first area (A1) into the third space (S3) through the fourth opening (H4).

As described above, the main body box (110) has a first surface (F1). The main body box (110) has a first partition plate (115b) that divides the inside of the main body box (110) into an accommodation space (S0) that accommodates the first heat-generating components (120a, 120b) and the fan (140), and a first space (S1) that faces the first surface (F1).

On a surface of the main body box (110) other than the first surface (F1), an inlet (H3) is formed to introduce air from outside the main body box (110) into the first space (S1), and a first opening (H1) is formed to exhaust air from within the storage space (S0) to the outside by the fan (140). A second opening (H2) is formed in the first partition plate (115b).

The second partition plate (rear plate (115a)) divides the inside of the main body box (110) into a storage space (S0) and a second space (S2) facing at least a portion of the multiple side surfaces (F3). The first space (S1) and the second space (S2) are in communication. The inlet (H3) is formed in at least a portion of the multiple side surfaces (F3) that constitute the second space (S2).

<Cooling of heat-generating components>
The arrows in Fig. 5 indicate the flow of air. In the electrical component box (100), when the fan (140) is operated, an air flow is formed in the first area (A1) from the second opening (H2) toward the fan (140). When the fan (140) is operated, air in the first space (S1) is drawn into the first area (A1) through the second opening (H2).

The first space (S1) and the second space (S2) are connected. Therefore, when the air in the first space (S1) flows into the first area (A1), the air in the second space (S2) flows into the first space (S1).

When air moves from the second space (S2) to the first space (S1), air outside the electrical component box (100) is taken into the second space (S2) through the third opening (H3). The air taken into the second space (S2) (outside air) flows through the first space (S1) and then the second opening (H2) and enters the first area (A1).

The air in the first area (A1) is exhausted by the fan (140) through the fourth opening (H4) into the third space (S3). The air in the third space (S3) is exhausted to the outside of the electrical component box (100) through the first opening (H1) formed in the bottom cover (113).

When the converter circuit operates in the electrical equipment box (100), the first heat-generating components (120a, 120b) generate heat. The heat of the first heat-generating components (120a, 120b) is cooled by the air flow formed in the first area (A1) as described above. The air that has cooled the first heat-generating components (120a, 120b) is discharged to the outside of the electrical equipment box (100) through the first opening (H1).

When the inverter circuit operates in the electrical component box (100), the second heat-generating component (130b) generates heat. In the second space (S2), there is an air flow from the third opening (H3) toward the first space (S1). In other words, air taken in from outside the electrical component box (100) flows around the heat dissipation fins of the heat sink (130a).

The heat sink (130a) dissipates heat from the second heat-generating component (130b) to the air in the second space (S2). As a result, the second heat-generating component (130b) is cooled. The air that has cooled the second heat-generating component (130b) is ultimately discharged to the outside of the electrical component box (100) through the first opening (H1).

Effects of this embodiment
Various pipes may be installed above the ceiling in which the ventilation device (20) is installed. In the ceiling, water droplets may fall from the pipes toward the electrical component box (100) for some reason.

In the electrical component box (100), air for cooling the first heat-generating component (120a, 120b) and the second heat-generating component (130b) is taken in through the third opening (H3).

The first opening (H1) and the third opening (H3) are formed on a surface other than the first surface (F1). Specifically, the third opening (H3) is formed on the third surface (F3). The third surface (F3) is a surface that extends in the vertical direction on the rear cover (111). Falling water droplets are unlikely to hit the third surface (F3) that extends in the vertical direction. In other words, falling water droplets are unlikely to enter the third opening (H3).

The first opening (H1) is formed in the fifth surface (F5). The fifth surface (F5) is a surface that extends in the vertical direction on the bottom cover (113). Falling water droplets are unlikely to hit the fifth surface (F5) that extends in the vertical direction. In other words, water droplets falling from above the electrical component box (100) are unlikely to enter the first opening (H1).

The second opening (H2) is covered by a top cover (112). In the electrical component box (100), water does not fall directly into the second opening (H2).

The periphery of the second opening (H2) is burred. Even if water droplets get into the first space (S1) for some reason, the raised edge created by this burring can prevent water from entering the storage space (S0) through the second opening (H2).

As described above, the electrical equipment box (100) can prevent falling water from entering the electrical equipment box (100).

The ventilation device (20) of this embodiment can be placed upside down. When the ventilation device (20) is placed upside down, the electrical component box (100) is also placed upside down. Specifically, the first surface (F1) of the main body box (110) of the electrical component box (100) is on the bottom side and the fourth surface (F4) is on the top side.

Even if the electrical equipment box (100) is placed upside down, the third surface (F3) and the fifth surface (F5) are surfaces that extend in the vertical direction. In other words, the first opening (H1) and the third opening (H3) are unlikely to be hit by water droplets falling from above the electrical equipment box (100).

The fourth opening (H4) is covered by a bottom cover (113). Even if the electrical equipment box (100) is positioned so that the F4 side faces upward, water will not fall directly into the fourth opening (H4).

The periphery of the fourth opening (H4) is burred. If the electrical equipment box (100) is placed upside down, and water droplets enter the third space (S3) for some reason, the raised edge created by the burring can prevent water from entering the storage space (S0) through the fourth opening (H4).

As described above, the electrical equipment box (100) can prevent falling water from entering the electrical equipment box (100) even when the ventilation device (20) is placed upside down.

In the electrical component box (100), the storage space (S0) is divided into two regions (A1, A2) by the partition plate (116). The first heat-generating component (120a, 120b) and the second heat-generating component (130b) are arranged in different regions (A1, A2). In the electrical component box (100), air suitable for cooling the first heat-generating component (120a, 120b) and the second heat-generating component (130b) can be supplied. In the electrical component box (100), the heat-generating components (120a, 120b, 130b) can be efficiently cooled. This is because the partition plate (116) allows the cooling air to be introduced intensively into the first region (A1).

Second Embodiment
9 is a schematic diagram showing a cross-sectional structure of an electrical component box (100) according to embodiment 2. The electrical component box (100) according to embodiment 2 does not include a rear cover (111) and a bottom cover (113) that are included in the electrical component box (100) according to embodiment 1. The configuration of a top cover (112) (second cover) according to embodiment 2 is different from that of the top cover (112) according to embodiment 1.

Figure 10 is a perspective view that shows a schematic structure of the top cover (112) in embodiment 2. The top cover (112) in embodiment 2 has a plurality of slit-shaped inlets (H6) formed in at least a portion of the side surface (F6) that extends in the vertical direction of the top cover (112) in embodiment 1.

In this example, the side surface (F6) extends vertically when the electrical component box (100) is installed. In the following, the side surface (F6) is also referred to as the sixth surface. The inlet (H6) is also referred to as the sixth opening.

<Cooling of heat-generating components>
The arrows in Fig. 9 indicate the flow of air. When the fan (140) is operated in the electrical component box (100), an air flow is formed in the first area (A1) from the second opening (H2) toward the fan (140). Air outside the electrical component box (100) is taken into the first space (S1) through the inlet (H6).

The air taken into the first space (S1) enters the first area (A1) through the second opening (H2). The air in the first area (A1) is exhausted by the fan (140) to the outside of the electrical component box (100) through the fourth opening (H4).

When the converter circuit operates in the electrical equipment box (100), the first heat-generating components (120a, 120b) generate heat. The heat of the first heat-generating components (120a, 120b) is cooled by the air flow formed in the first area (A1) as described above. The air that has cooled the first heat-generating components (120a, 120b) is discharged to the outside of the electrical equipment box (100) through the fourth opening (H4).

In the second embodiment, there is no rear cover (111). The heat sink (130a) dissipates heat to the air outside the housing portion (115) (in other words, the air outside the electrical component box (100)). As a result, the second heat-generating component (130b) is cooled.

Effects of this embodiment
The sixth opening (H6) is formed in a surface other than the first surface (F1). With this configuration, in this embodiment as well, the infiltration of fallen water into the electrical component box (100) is suppressed.

More specifically, the inlet (H6) is provided on the side surface (F6). The side surface (F6) is a surface that extends in the vertical direction on the top cover (112). Falling water droplets are unlikely to hit the side surface (F6) that extends in the vertical direction. In other words, water droplets falling from above the electrical component box (100) are unlikely to enter the inlet (H6). The electrical component box (100) of embodiment 2 can also prevent falling water from entering the electrical component box (100).

Third Embodiment
11 is a schematic cross-sectional view of an electrical component box (100) according to embodiment 3. The electrical component box (100) according to embodiment 3 does not include the rear cover (111) that is included in embodiment 1. The top cover (112) (second cover) in embodiment 3 is the same as the top cover (112) employed in embodiment 2.

The electrical equipment box (100) of embodiment 3 can be placed upside down. Figure 11 shows the upside down state.

<Cooling of heat-generating components>
The arrows in Fig. 11 indicate the flow of air. When the fan (140) in the electrical component box (100) is operated, an air flow is formed in the first area (A1) from the second opening (H2) toward the fan (140). As a result, air outside the electrical component box (100) is taken into the first space (S1) through the inlet (H6) (sixth opening).

The air taken into the first space (S1) enters the first area (A1) through the second opening (H2). The air in the first area (A1) flows into the third space (S3) by the fan (140). The air in the third space (S3) is exhausted outside the electrical component box (100) through the first opening (H1) formed in the bottom cover (113).

When the converter circuit operates in the electrical equipment box (100), the first heat-generating components (120a, 120b) generate heat. The heat of the first heat-generating components (120a, 120b) is cooled by the air flow formed in the first area (A1) or the like as described above. The air that has cooled the first heat-generating components (120a, 120b) is discharged to the outside of the electrical equipment box (100) through the first opening (H1).

In the third embodiment, there is no rear cover (111). The heat sink (130a) dissipates heat to the air outside the housing portion (115) (in other words, outside the electrical component box (100)). As a result, the second heat-generating component (130b) is cooled.

Effects of this embodiment
The first opening (H1) is provided in the side surface (F5) (fifth surface). The inlet (H6) is provided in the side surface (F6) (sixth surface). The side surfaces (F5) and (F6) are surfaces that extend in the vertical direction when the electrical component box (100) is installed.

Falling water droplets are unlikely to hit the fifth surface (F5) and the side surface (F6) that extend in the vertical direction. In other words, water droplets falling from above the electrical component box (100) are unlikely to enter the first opening (H1) and the inlet (H6). The electrical component box (100) of embodiment 3 can also prevent falling water from entering the electrical component box (100).

Other Embodiments
In the first to third embodiments, instead of the covers (first to third covers), a partition plate may be provided in the storage section (115) to define the first space (S1), the second space (S2), etc. by the partition plate.

The third opening (H3) may be provided on the second surface (F2). Since the second surface (F2) also extends in the vertical direction, even if the third opening (H3) is provided on the second surface (F2), falling water droplets are less likely to enter the third opening (H3).

The shapes, numbers, and sizes of the illustrated first opening (H1), third opening (H3), sixth opening (H6), etc. are merely examples. These openings are not limited to the illustrated examples.

The location of the fan (140) is an example. The fan (140) may be installed at another location within the first area (A1). The number of fans (140) is also an example. Additional fans (140) may be added.

Although the embodiments and modifications have been described above, it will be understood that various modifications of form and details are possible without departing from the spirit and scope of the claims. Elements of the above embodiments, modifications, and other embodiments may be combined or substituted as appropriate.

As described above, the present disclosure is useful for electrical equipment boxes and ventilation devices.

20. Ventilation system
100 Electrical equipment box
110 Main unit box
115a Back panel (second partition panel)
115b Top plate (first partition plate)
120a, 120b First heat generating component
130a Heatsink
130b Second heat generating component
140 Fans
A1 First Area
A2 Second Area
F1 Side 1
F2, F3 side
H1 First opening
H2 Second opening
H3, H6 entrance
S0 Containment Space
S1 First Space
S2 Second Space

Claims (5)

The device includes a first heat generating component (120a, 120b), a fan (140), and a main body box (110),
The main body box (110) is
The first page (F1) and
a first partition plate (115b) that divides the inside of the main body box (110) into an accommodation space (S0) that accommodates the first heat generating components (120a, 120b) and the fan (140) and a first space (S1) facing the first surface (F1);
Equipped with
inlets (H3, H6) for introducing air outside the main body box (110) into the first space (S1) and a first opening (H1) for discharging air within the storage space (S0) to the outside by the fan (140) are formed on a surface of the main body box (110) other than the first surface (F1),
A second opening (H2) is formed in the first partition plate (115b).
Electrical equipment box. The electrical equipment box according to claim 1,
The main body box (110) is
a plurality of side surfaces (F2, F3) different from the first surface (F1) extending in a vertical direction when the main body box (110) is installed;
a second partition plate (115a) that divides the inside of the main body box (110) into the storage space (S0) and a second space (S2) facing at least a part of the plurality of side surfaces (F2, F3);
Equipped with
The first space (S1) and the second space (S2) are in communication with each other,
The inlet (H3, H6) is formed in at least a part of the plurality of side surfaces (F2, F3) constituting the second space (S2).
Electrical equipment box. The electrical equipment box according to claim 2,
A second heat generating component (130b) and a heat sink (130a),
The heat sink (130a) dissipates heat from the second heat generating component (130b) to the second space (S2).
Electrical equipment box. The electrical equipment box according to claim 3,
a third partition plate (116) that divides the accommodation space (S0) into a first area (A1) in which the first heat generating component (120a, 120b) is accommodated and a second area (A2) in which the second heat generating component (130b) is accommodated;
The second opening (H2) opens into the first region (A1),
The fan (140) is provided in the first area (A1).
Electrical equipment box. A ventilation device equipped with an electrical equipment box according to any one of claims 1 to 4.