JP2011176135A - Cooling method and cooling facility of electric control panel - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cooling method and a cooling facility of an electric control panel which can efficiently cool the electric control panel inside an electric chamber. <P>SOLUTION: In the cooling method of the electric control panels arranged in parallel oppositely with an interval on a floor in the electric chamber 1 and including a cool air sucking surface arranged on an opposite surface side, a cool air discharge duct 10 is arranged to extend along an electric control panel array 7, above between cool air sucking surface sides of the opposite electric control panel arrays 7, and cool air is discharged from the cool air discharge port 11 arranged along a lower surface side of the cool air discharge duct 10. In addition, a partition section 13, formed of an insulating partition plate or an air curtain, blocks a cool air region 14 between front surface sides of the electric control panel array 7 and a warm air region 15, on a back surface side of the electric control panel array 7. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a method for cooling an electric control panel in which low-temperature air is allowed to flow inside an electric control panel such as a computer room.

Conventionally, as shown in FIG. 5, warm air (warm air 15 a) exhausted from the front-side outlet and the upper outlet of the electric control panel row 7 arranged in parallel on the floor in the electric chamber 1 is arranged in the electric chamber. 1 is sucked from the indoor unit 17a in the air conditioner installed in 1 and cooled by the outdoor unit in the air conditioner to return low-temperature air (cold air 14a) to the electric chamber 1, and the returned low-temperature air is returned to the back of the electric control panel row 7. There is known a method of cooling an electric control panel that sucks in from a side entrance.
In the case shown in FIG. 5, the warm air 15a and the cool air 14a are mixed in the electric room. Therefore, the cool air 14a from the back side of the electric control panel is mixed with the warm air 15a, and the cooling efficiency of the electric control panel is low. There is a problem.

  As a technique for improving the cooling efficiency of the technique shown in FIG. 5, low-temperature air blown from a cold air outlet of an air conditioner is caused to flow into the floor pit 6 in the electric room, and electricity is utilized using the lower and upper openings of the electric panel. There is a cooling method in which low-temperature air is passed through the inside of the panel (for example, see Patent Document 1).

  Further, in the case where there are a plurality of control panel rows in the electrical room, the control panel rows in which the intake surface of the control panel row is arranged on the front surface and the exhaust surface is arranged on the back surface or the upper surface, the control panels facing each other at intervals It is also known that the exhaust surfaces are arranged on the opposite back side or upper side with the air intake surfaces of the rows facing each other, and cold air is blown out from an air conditioning outlet provided at a pinpoint on the ceiling (for example, Patent Documents) 2).

JP 2000-179926 A JP 2009-71084 A

In each of the above conventional cases, cold air and warm air are not reliably separated in the electric room, so that they are mixed or the heat insulating effect of the partition plate is not sufficient, or the exhaust port is pinpointed on the indoor side wall or ceiling part. Since the cool air is provided and exhausted, the indoor warm air 15a and 14a are not reliably separated, and there is a problem that the cooling efficiency is lowered.
In addition, as shown in FIG. 6, when there is a wiring pit below the floor and the wiring pit can be used as a ventilation path, control is performed on the floor 5 of the electrical chamber 1 to face each other at an interval. A strip-like horizontal partition plate 25 is provided horizontally along the electric control panel row 7 above the intake surface 8 side of the panel row 7, and cold air outlets (not shown) are provided on both sides in the width direction of the horizontal partition plate 25. In addition, the cool air is allowed to flow from below the floor, the air is sucked in from the cool air intake surface 8 on the front side of each opposing control panel row 7, and the warm air 15a is exhausted from the exhaust surface 9 on the back side or upper surface side of the control panel row 7. A technique for supplying cold air to the wiring pit from an indoor exhaust port (not shown) via an outdoor air conditioner is also conceivable. However, when the wiring pit cannot be used as an air passage, a cooling method of the form shown in FIG. Cannot be adopted.
It is an object of the present invention to provide an electric control panel cooling method and cooling equipment that can efficiently cool an electric control panel in an electric room.

In the electric control panel cooling method according to the first aspect of the present invention, the electric control panel rows having the cold air intake surface on the front side with a space on the floor in the electric room are arranged in parallel and the cold air intake surface is opposed to each other. In the cooling method of the control panel, a cold air discharge duct is provided above the cold air intake surface side of the electric control panel row so as to extend along the electric control panel row, and the cold air provided below the cold air discharge duct. It is characterized in that cold air is discharged from the discharge port.
According to a second aspect of the invention, in the method for cooling an electric control panel according to the first aspect of the invention, the outer surface of the cold air discharge duct is heat-insulated, and the lower portions of both side walls of the cold air discharge duct and the upper front surface of the electric control panel row are provided. It is characterized in that the cool air region between the front side of the electric control panel row and the warm air region on the rear side of the electric control panel row are cut off by connecting with the partition part.
In the third invention, in the method for cooling the electric control panel according to the first or second invention, the cool air discharge duct is provided away from the ceiling portion, and the convection between the warm air on the back side of each electric control panel row is enabled. It is characterized by that.
According to a fourth invention, in the method for cooling an electric control panel according to the first to third inventions, a heat insulating layer is provided on the outer wall and the ceiling roof to improve the cooling efficiency of the electric control panel.
According to a fifth aspect of the present invention, in the method for cooling an electric control panel according to the first to fourth aspects of the present invention, the warm air intake port, the cool air discharge port of the electric room, and the outdoor unit in the air conditioner provided outside are respectively connected to the warm air supply path. It is connected through a cold air supply path.
According to a sixth aspect of the present invention, in the electric control panel cooling method according to the first to fifth aspects of the present invention, when the electric control panel is provided with an odd number of rows of 3 or more, it is spaced from the cold air intake surface of the electric control panel that is not paired. A partition wall is provided so as to be opposed to each other, and a cold air discharge duct is provided so as to extend along the electrical control panel row above the cold air intake surface side of the non-paired electric control panel row and the partition wall. The cool air discharge duct provided at the lower side of the cool air discharge duct discharges cool air to form a cool air region, and the cool air in the cold air region is sucked from the cool air intake surface side.
In the electric control panel cooling facility according to the seventh aspect of the present invention, the electric control panel rows having the cold air intake surface on the front side with a space on the floor in the electric room are arranged in parallel and the cold air intake surface is opposed to each other. In the cooling equipment of the control panel, a cold air discharge duct is provided above the cold air intake surface side of the electric control panel row so as to extend along the electric control panel row, and a cold air discharge port is provided below the cold air discharge duct. Is provided.
According to an eighth aspect of the present invention, in the cooling equipment for an electric control panel according to the seventh aspect, the outer surface of the cold air discharge duct is heat-insulated.
In the ninth invention, in the cooling facility for the electric control panel according to the seventh or eighth invention, the cold air discharge duct is provided away from the ceiling portion, and an air passage is provided between the upper side of the cold air discharge duct and the ceiling portion, It is characterized in that warm air mutual convection on the back side of each electric control panel row is enabled.
According to a tenth aspect, in the cooling facility for an electric control panel according to any one of the seventh to ninth aspects, a heat insulating layer is provided on the outer wall and the ceiling roof.
In the eleventh aspect of the invention, in the cooling facility for the electric control panel according to any one of the seventh to tenth aspects, the warm air intake port, the cold air discharge port of the electric room, and the outdoor unit provided in the outdoor air conditioner It is connected through an air passage and a cold air supply passage.
In the twelfth invention, in the cooling equipment for the electric control panel according to any one of the seventh to eleventh inventions, when the electric control panel is provided with an odd number of three or more rows, the electric control of the odd-numbered columns which are not paired A partition wall is provided so as to face the cold air intake surface of the panel with a space therebetween, and a cold air discharge duct is disposed above the partition between the cold air intake surface side and the partition wall of the odd-numbered odd-numbered electric control panel row. It is provided so as to extend along the electric control panel row, and cool air is discharged from a cold air discharge port provided below the cold air discharge duct, thereby forming a cold air region.

According to the present invention, the cold air discharge duct is provided so as to extend along the electric control panel row above the cold air intake surface side of the opposing electric control panel row or above the cold air suction surface and the partition wall. Since the air is discharged from the cold air discharge port provided along the lower side of the discharge duct, it is possible to reliably cool the electric control panel by sending cool air along the longitudinal direction of the electric control panel row. The lower part of both side walls of the cool air discharge duct covered with heat insulation and the upper part of the front of the electric control panel row are connected by a partition part, so that the cold air region between the front side of the electric control panel row and the warm air region on the rear side of the electric control panel row are provided. Since it shuts off, cold air and warm air are reliably separated and supplied, and the cooling efficiency of the electric control panel by cold air can be enhanced.
In addition, since the cool air discharge duct is provided apart from the ceiling portion to allow convection between warm airs on the back side of each electric control panel row, it is possible to suppress an increase in temperature difference between the warm air regions.
In addition, since the heat insulating layer is provided on the outer wall and the ceiling roof, the cooling efficiency of the electric control panel can be improved in summer and the like.
In addition, since the warm air intake and cold air outlets of the electrical room and the outdoor unit in the air conditioner provided outside are connected via the warm air supply path and the cold air supply path, respectively, heat exchange such as inverter air conditioners It can be cooled by an air conditioner equipped with a vessel.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 shows a cooling facility for an electric control panel according to an embodiment of the present invention, and is a longitudinal front view showing a state in which the electric control panel is cooled. It is the sectional view on the AA line of FIG. It is a vertical front view which shows the cooling equipment of the electric control panel of other embodiment of this invention, Comprising: The state which is cooling the electric control panel is shown. FIG. 4 is a sectional view taken along line BB in FIG. 3. It is explanatory drawing of the 1st example of the cooling equipment of the conventional electric control panel. It is explanatory drawing of the 2nd example of the cooling equipment of the conventional electric control panel.

    Next, the present invention will be described in detail based on the illustrated embodiment.

  1 and 2 show an embodiment of a cooling facility for an electric control panel according to a first embodiment of the present invention.

  First, the housing structure and equipment shown in FIG. 1 and FIG. 2 will be briefly described. The electric chamber 1 such as a computer room is surrounded by a heat insulating outer wall or inner wall 2 at its peripheral side. At the same time, the upper part is a heat insulating roof or a heat insulating ceiling 3.

A wiring pit 6 is provided under the floor 5 provided on the underfloor housing 4, and the electric chamber 1 is provided on the floor 5, so that circulation between the air in the electric chamber 1 and the air in the wiring pit 6 is not expected. It is in the form.
On the floor 5, an electric control panel row 7 having a cold air intake surface on the front side which is arranged to extend in the front-rear direction is arranged so as to be opposed to each other at an interval in the left-right direction. Specifically, the electric control panel row 7 is arranged so that the cold air intake surfaces face each other in parallel, and the adjacent electric control panel row 7 provided with an entrance for sucking the cold air 14a on the front side. A cold air intake surface 8 is provided, and a warm air exhaust surface 9 having a discharge outlet for discharging warm air 15 a is provided on the back side and the top surface side of each electric control panel row 7.

  A cold air discharge duct 10 extends along the electric control panel row 7 at a lower position sufficiently away from the heat insulating roof or the heat insulating ceiling portion 3 above the cold air intake surface 8 side of the opposing electric control panel row 7. The width of the cold air discharge duct 10 is approximately the same between the electric control panel rows 7, and the outer surface of each cold air discharge duct 10 is covered with heat insulation.

  It discharges from the cold air discharge port 11 over the entire length of the electric control panel row 7 provided continuously along the lower surface side of each cold air discharge duct 10.

  The lower part of both heat insulating side walls 12 of the cold air discharge duct 10 and the upper part of the front surface of each electric control panel row 7 are provided with heat insulating partition plates, or the front surface of the electric control panel row 7 from the blowout port at the lower part of both heat insulating side walls 12. Cold air is blown out toward the upper portion to form an air curtain, and a partition portion 13 is formed by a heat insulating partition plate or an air curtain. The partition portion 13 is electrically controlled with the lower portions of both heat insulating side walls 12 of the cold air discharge duct 10. It is provided over the entire length of each electric control panel row 7 so as to connect the front upper part of the panel row 7, and the partition portion 13 causes a cold air region (cold aisle) 14 between the electric control panel row 7 front side and the electric The warm air region (hot aisle) 15 on the back side of the control panel row 7 is cut off.

Further, the cool air discharge duct 10 is provided away from the heat insulating roof or the heat insulating ceiling portion 3, and the air passage 16 is provided between the upper side of the cold air discharge duct 10 and the heat insulating roof or the heat insulating ceiling portion 3. . By providing the ventilation passage 16, when there is a change in the airflow between the warm airs on the back side of each electric control panel row 7 or when a temperature difference occurs, convection of air in these warm airflow regions is possible. I have to. A building provided with the electric control panel 7 has a large temperature difference (external load) between the side receiving sunlight 22 or the like due to the season or sunshine and the side not receiving sunlight, etc. By providing 16, the back side of each electric control panel row 7 is allowed to convection with each other to suppress the temperature difference between the warm air regions 15 from increasing.
Further, by providing a heat insulating layer on the outer wall and the ceiling roof, the cooling efficiency of the electric control panel 7 by the air conditioner 17 composed of an inverter air conditioner can be improved even in the summer (or in the daytime when much sunlight is received). I try to improve. When the outside air temperature is low in winter or at night, an appropriate temperature detector is provided so as to reduce the number of operating air conditioners 17, and the motor of the heat exchanger in the outdoor unit 17b is controlled by an inverter. Yes.

  The warm air inlet 18 of the electric room 1, the proximal end side of the cool air discharge duct 10, and the outdoor unit 17 of the air conditioner 17 including an inverter air conditioner provided outside are connected via a warm air supply path 19 and a cold air supply path 20, respectively. Connected.

  In the cooling system for the electric control panel shown in FIGS. 1 and 2, even if the wiring pit 6 is provided below the floor 5 or the wiring pit 6 cannot be used as a ventilation path, the electric control panel row In the meantime, the cold air can be discharged from the cold air discharge port 11 so that the cold air region 14 can be reliably formed, and since it does not mix with the warm air discharged from the back surface or the upper surface of the electric control panel 7, the electric control panel 7 can be reliably connected. The dehumidified cold air is supplied to the electric control panel 7 so that it can be efficiently cooled.

  If the floor 5 can be ventilated, the electric control panel 7 can be further cooled by supplying the cold air to the electric chamber 1 using the wiring pit 6 as the air passage 16. In order to prevent condensation in the wiring pit 6, the floor 5 is preferably configured so as not to allow ventilation.

  3 and 4 show a case where an odd number of electric control panel rows 7 are provided in a cooling facility for an electric control panel according to another embodiment of the present invention. When the electric control panel row 7 is provided in an even number, as in the above-described embodiment, the two electric control panel rows 7 are set as one set of electric control panel rows, and a pair of adjacent electric control panels What is necessary is just to make it a warm air area | region between row groups, but when arrange | positioning the odd-numbered electric control panel row | line | column 7 of 3 or 3 or more so that the odd-numbered electric control panel row | line | column 7 which is not paired may arise. Therefore, in this case, as shown in FIG. 3 and FIG. 4, the heat-insulating partition walls 23 are arranged at positions away from the inside of the heat-insulating outer wall 2, and the odd-numbered electric control panel rows are not paired. 7 is provided so as to face the cold air intake surface 8 with an interval, and the cold air is discharged from the cold air discharge port 11 between the outermost odd-numbered electric control panel row 7 and the heat insulating partition wall 23. 14, and a cool air discharge duct 10 and a partition 13 are provided on the upper side. It is sufficient.

  In the case of the form shown in FIGS. 3 and 4, the electric control panel is cooled by a plurality of air conditioners 17, but one air conditioner 17 and the electric chamber 1 may be connected. .

  The present invention is advantageous when an underfloor pit cannot be used as a cool air passage or when an electric control panel of an electric room in which a wiring rack is not provided on the ceiling of the electric room is cooled.

DESCRIPTION OF SYMBOLS 1 Electrical room 2 Outer wall or inner wall 3 Thermal insulation roof or thermal insulation ceiling part 4 Underfloor frame 5 Floor 6 Wiring pit 7 Electric control panel row 8 Cold air intake surface 9 Warm air exhaust surface 10 Cold air discharge duct 11 Cold air discharge port 12 Heat insulation side wall 13 Partition Part 14 Cold air region 14a Cold air 15 Warm air region 15a Warm air 16 Air passage 17 Air conditioner 17b Outdoor unit 17a Indoor unit 18 Warm air inlet 19 Warm air air passage 20 Cold air air passage 21 Entrance / exit 22 Sunlight 23 Partition wall 25 Horizontal partition plate

Claims (12)

  In the cooling method of the electric control panel provided such that the electric control panel rows having the cold air suction surface on the front side with a space on the floor in the electric room are arranged in parallel and the cold air suction surfaces face each other, A cold air discharge duct is provided above the cold air intake surface so as to extend along the electric control panel row, and cool air is discharged from a cold air discharge port provided below the cold air discharge duct to form a cold air region. An electric control panel cooling method, wherein cold air in the cold air region is sucked from the cold air intake surface side.   The outer surface of the cold air discharge duct is covered with heat insulation, and the lower part of both side walls of the cold air discharge duct and the front upper part of the electric control panel row are connected by a partition part, and a cold air region between the front side of the electric control panel row The electric control panel cooling method according to claim 1, wherein a warm air region on the back side of the electric control panel array is cut off.   The method for cooling an electric control panel according to claim 1 or 2, wherein a cooling air discharge duct is provided apart from the ceiling portion to enable mutual convection of warm air on the back side of each electric control panel row.   The method for cooling an electric control panel according to any one of claims 1 to 3, wherein a heat insulating layer is provided on the outer wall and the ceiling roof to improve the cooling efficiency of the electric control panel.   5. A warm air intake port, a cold air discharge port of an electric room, and an outdoor unit in an air conditioner provided outside are connected via a warm air supply path and a cold air supply path, respectively. The method for cooling an electric control panel according to any one of the above.   When the electric control panel is provided with an odd number of rows of 3 or more, a partition wall is provided so as to face the cold air intake surface of the non-paired electric control panel at an interval, A cold air discharge duct is provided above the cool air intake surface side and the partition wall so as to extend along the electric control panel row, and the cold air is discharged from the cold air discharge port provided below the cold air discharge duct. 6. The method of cooling an electric control panel according to claim 1, wherein a region is formed, and cold air in the cold region is sucked from the cold air intake surface side.   In a cooling facility for an electric control panel provided such that an electric control panel row having a cold air intake surface on the front side with a space on the floor in the electric room is arranged in parallel and the cold air intake surface faces each other, An electric control panel characterized in that a cold air discharge duct is provided above the cold air intake surface side so as to extend along the electric control panel row, and a cold air discharge port is provided along the lower side of the cold air discharge duct. Cooling equipment.   The cooling facility for an electric control panel according to claim 7, wherein an outer surface of the cold air discharge duct is heat-insulated.   A cool air discharge duct is provided separately from the ceiling, and a ventilation path is provided between the upper side of the cold air discharge duct and the ceiling to enable convection between warm air on the back side of each electric control panel row. The cooling equipment for an electric control panel according to claim 7 or 8.   The heat-insulating layer is provided in an outer wall and a ceiling roof, The cooling equipment of the electric control panel of any one of Claims 7-9 characterized by the above-mentioned.   The warm air intake port, the cold air discharge port of the electric room, and the outdoor unit in the air conditioner provided outside are connected via a warm air supply path and a cold air supply path, respectively. The cooling equipment for the electric control panel according to any one of the above.   When the electric control panel is provided with an odd number of rows of 3 or more, a partition wall is provided so as to face the cold air intake surface of the odd-numbered electric control panel that is not paired with an interval, and the odd number that is not paired A cold air discharge duct is provided so as to extend along the electric control panel row above the cold air intake surface side of the row of electric control panel rows and the partition wall, and provided below the cold air discharge duct. The cooling equipment for an electric control panel according to any one of claims 7 to 11, wherein a cool air region is formed by discharging cool air from a cold air discharge port.

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