JP2007020295A - Cabinet device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cabinete device excellent in coolability where there is no necessity to complicate the structure of the cabinet used for a distribution panel or to enlarge it and it is possible to keep the atmosphere within the cabinet clean. <P>SOLUTION: This cabinet device is equipped with a cabinet 1 which accommodates electrical equipment, an outside air inflow path 4 which is provided at the specified part of this cabinet, an air cleaning filter 5 which is interposed in this outside air inflow path so as to remove a variety of dust or salt within the air, a fan 6 which is arranged within the above outside air inflow path so as to let outside air flow in and keeps the inside of the above cabinet in a state of being pressurized more than outside, and an exhaust vent 10 for air within cabinet which is provided at the specified part of the above cabinet. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a forced ventilation type casing device that can be preferably used as, for example, a distribution board, a distribution board, a control panel, an unmanned relay device, a cubicle device, or the like in which electrical devices are accommodated.

  As a switchboard, which is a casing device configured to perform conventional forced ventilation, a ventilation path is formed between the device mounted on the device mounting plate and the back plate of the box body over the top and bottom of the box body. A suction port is formed in the lower front of the box body that is closed, and a discharge port is formed in the upper front, and a fan is provided to exhaust the intake air from the suction port through the discharge port. There is one that suppresses the temperature rise of the internal temperature (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 6-22416 (first page, FIG. 1)

  In the switchboard with forced ventilation inside the conventional panel as described above, when ventilating with an exhaust fan, the air pressure inside the panel drops compared to the outside and the inside of the panel is exposed from the gap between the frame and the door, cover, etc. There is a problem that harmful substances such as dust and water drops enter, and if the airtightness of the casing constituting the panel is increased to avoid this, the structure of the casing becomes complicated. In addition, in order to reduce the pressure loss on the intake side, there is a problem that the opening area has to be increased and the housing size needs to be increased.

  The present invention has been made to solve the above-described problems of the prior art, and cooling that can keep the atmosphere inside the housing clean without complicating or increasing the size of the housing structure. It aims at providing the housing apparatus excellent in property.

  A casing device according to the present invention includes a casing that houses electrical devices, an outside air inflow path that is provided through a predetermined portion of the casing, and an outside air that flows from the outside air inflow path into the casing. A fan that holds the inside of the housing in a more pressurized state than the outside, an air purification filter that removes dust in the outside air disposed in the outside air inflow passage, and a predetermined portion of the housing And an air exhaust port provided.

  In the present invention, an air purification filter that removes dust in the outside air is interposed in the outside air inflow passage, and a fan that holds the inside of the housing in a pressurized state from the outside is provided. Because it is kept clean in a constantly pressurized state and prevents the inflow of outside air from the gap, the housing structure does not become complicated or large due to airtightness, and has excellent cooling performance Is effective.

Embodiment 1 FIG.
FIG. 1 conceptually shows the main part of an outdoor type switchboard which is a casing device according to Embodiment 1 of the present invention. FIG. 1 (a) is a front view, and FIG. 1 (b) is FIG. It is arrow sectional drawing in the Ib-Ib line | wire of a). In the figure, the casing 1 constituting the switchboard is configured by horizontally connecting a panel a and a panel b configured by using a frame. Each open / close door 2 is provided. A ventilation duct 3 for preventing raindrops from entering is provided in the upper front portion and the rear portion of the panel a, and an outside air inflow passage 4 for taking in outside air is formed using the ventilation duct 3. An air purification filter 5 for removing dust, salt, etc. in the outside air is detachably provided on the inside of the housing 1 of the outside air inflow path 4, and outside air is forcibly taken inside the housing 1. An intake-type fan 6 is provided that holds the inside in a more pressurized state than the outside.

  In this example, a transformer 7 is installed in the panel a, and the protection inside the panel is provided for protection from the high voltage portion (not shown) of the transformer 7 between the inside of the open / close door 2 and the transformer 7. A cover 8 is provided. The in-panel protective cover 8 is plate-shaped and partially formed in a wire mesh shape, and covers from the lower part of the fan 6 to the bottom surface of the housing 1. A plate-like partition member 9 for controlling the flow of the outside air sucked from the outside air inflow passage 4 is provided at the connecting portion between the panel a and the panel b, and the partition member 9 is provided inside the panel a and the panel b. A communication portion 9a for closing the upper space and opening the lower space to circulate the air is formed.

  On the other hand, the upper front portion and the rear portion of the panel b are provided with an exhaust port 10 for the outside air introduced into the housing 1. The exhaust port 10 is covered with a duct having the same shape as the ventilation duct 3 in order to prevent raindrops and the like from entering from the outside. Further, in the panel b, for example, various electrical devices including some heat generating devices such as switches, relays, instruments, operation members, power conversion devices, etc. are accommodated, but the illustration is omitted. The thick arrows A to F indicate the air flow during operation, and the arrow F indicates air flowing out from a gap (not shown) formed between the door 2 and the casing of the panel a or b. Shows the flow.

  Next, the operation of the first embodiment configured as described above will be described. When the intake fan 6 attached to the panel a is operated, fresh outside air flows into the outside air inflow path 4 as shown by an arrow A and passes through the air purification filter 5 interposed in the outside air inflow path 4. Dust and salt are removed, and the purified air is always sent in the direction of arrows B, C, D in the casing 1 and stored in the panels a and b. For example, after depriving the heat generated from the heat generating device while maintaining a good atmosphere, the heat is released from the exhaust port 10 of the panel b in the direction of arrow E.

  In the first embodiment, the four fans 6 are configured so that the pressure in the panels a and b is always higher than the outside air, and the casing 1 does not have an airtight structure. A part of the air sucked in by the air 6 flows out as shown by an arrow F from any gap (not shown) such as between the opening / closing door 2 and the housing, and air containing dust from the outside of the housing 1 Intrusion into the housing 1 through the gap is prevented.

  As described above, according to the first embodiment, since most of the space in the housing 1 can be used as a passage for cooling air, the pressure loss in the housing 1 can be reduced. Since the opening area can be reduced on both sides, the ventilation duct 3 can be easily attached, and the opening / closing door 2 does not need to be provided with an opening. Since the inside of the housing 1 is always kept clean in a pressurized state, outside air that has not been purified cannot enter from the opening / closing door 2 or the gap between the side walls. Therefore, it is not necessary to install packings for keeping the airtightness in the gap between the casing 1 and the open / close door 2, and the effect is obtained that the structure does not need to be complicated or enlarged. .

  In addition, although the switchboard of FIG. 1 illustrated above demonstrated the case where the two housings of the board a and the board b formed in the frame structure were connected, it is not necessarily limited to the connected one. Absent. In addition, the number of connected units is not limited to the number of units connected. For example, three or more units may be connected. In such a case, the units are connected so that the outside air that has been sucked in reaches every corner of the housing 1. What is necessary is just to comprise a ventilation path in a zigzag shape by changing the position of the communication part 9a by the partition member 9 of a part to the upper part and the lower part one by one.

Embodiment 2. FIG.
FIG. 2 conceptually illustrates the main part of an indoor switchboard that is a casing device according to Embodiment 2 of the present invention. FIG. 2 (a) is a front view, and FIG. 2 (b) is FIG. This corresponds to a cross-sectional view taken along line IIb-IIb in (a), and the housed internal electrical devices are not shown. In the figure, an opening / closing door 2 having an exhaust port 11 in the lower portion is provided on the front surface portion of the housing 1, and the side surface portion and the back surface portion of the housing 1 are closed by side wall members 12 made of a plate material. The outside air suction path 4 is disposed behind the casing ceiling of the casing 1, an intake fan 6 is provided above the outside air suction path 4, and the air purification filter 5 is an outside air suction path below the fan 6. It is provided in the lower part of 4 so that attachment or detachment is possible. Since other reference numerals are the same as those in the first embodiment, description thereof is omitted.

  In the second embodiment configured as described above, the air sucked by the fan 6 as indicated by the arrow A is cleaned by removing dusts when passing through the air purification filter 5. To the inside of the housing 1 to create a clean air flow, and to maintain a good atmosphere for the electrical equipment and components (not shown) housed in the housing 1. The heat-generating device is cooled and then exhausted as indicated by an arrow E from an exhaust port 11 provided at the lower part of the door 2. Further, as in the first embodiment, since most of the space in the housing 1 can be used as a passage for cooling air, the pressure loss in the housing 1 can be reduced, and the exhaust port 11 of the door 2 has an opening area. Can be small.

  Since the air pressure inside the housing 1 is kept higher than the outside air as in the first embodiment, a part of the air passes through the gap between the door 2 and the side wall member 12 as indicated by the arrow F. By flowing out, air that has not been purified from the gap cannot enter the inside of the housing 1. Accordingly, a complicated structure for maintaining airtightness in a gap between the casing 1 and the door 2 or between the frame member (not shown) and the side wall member 12 constituting the casing 1 is not necessary. In addition, a casing device having excellent cooling performance can be obtained without increasing the size.

  In the above embodiment, the configuration is described as a simplified example. For example, the type and required number of fans 6, the required air volume, the required pressure inside the housing 1, and the flow path cross-sectional areas of the exhaust ports 10 and 11 are described. Needless to say, the air flow resistance, pressure loss, necessary ventilation, gap area, temperature conditions, and other design conditions are appropriately considered. In addition, for example, in the winter or when there is no need for cooling, such as during low loads, a temperature sensor is provided to reduce the rotation of the fan 6 to save power by continuously or stepwisely rotating the fan 6. You may comprise so that it may control to. Further, the outside air inflow path 4 is configured such that the flow passage cross-sectional area is widened by a duct or the like and the air purification filter 5 is disposed in the widened portion in order to reduce the pressure loss due to the air purification filter 5. preferable.

BRIEF DESCRIPTION OF THE DRAWINGS It shows notionally the principal part of the outdoor installation type switchboard which is a housing | casing apparatus by Embodiment 1 of this invention, Fig.1 (a) is a front view, FIG.1 (b) is FIG.1 (a). It is arrow sectional drawing in the Ib-Ib line. FIG. 2 (a) is a front view and FIG. 2 (b) is a front view of FIG. 2 (a). FIG. This corresponds to a cross-sectional view taken along line IIb-IIb.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Housing | casing, 2 Open / close door, 3 Ventilation duct, 4 Outside air inflow path, 5 Air purification filter, 6 Fan, 7 Transformer, 8 In-panel protective cover, 9 Partition member, 9a Communication part, 10, 11 Exhaust port, 12 Side wall Element.

Claims (2)

  A housing for housing electrical equipment, an outside air inflow passage provided through a predetermined portion of the housing, and an outside air inflow passage from the outside air inflow passage into the housing. A fan that holds the air in a pressurized state from the outside, an air purification filter that removes dust in the outside air disposed in the outside air inflow path, and an air exhaust port provided in a predetermined portion of the housing, A housing apparatus comprising: A plurality of the casings are connected in series, the outside air inflow path is provided in the casing at one end when connected, and the exhaust port is provided in the casing at the other end when connected, and the adjacent casing The casing device according to claim 1, further comprising a partition member that controls the ventilation path in the connecting portion.

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