JP3974609B2 - Cubicle - Google Patents

Description

  The present invention relates to a cubicle that is installed outdoors as a communication base station and includes a wireless device, a cooling device, a heat exchange device, and the like.

Conventionally, as a communication base station, a cubicle in which ancillary equipment such as a radio and a battery is accommodated is installed outdoors.
Usually, such a cubicle is installed outdoors, so that the temperature in the cubicle rises excessively in summer, and the operation of each device such as a wireless device tends to be adversely affected. Therefore, it is known to include a cooling device in order to stably operate each device such as a wireless device (see, for example, Patent Document 1).
Specifically, an indoor unit is installed inside the cubicle, and an outdoor unit is installed outside. The air inlet of the indoor unit is formed on an arbitrary wall surface in the cubicle, and the floor on the wall side facing the air inlet is formed. An air outlet is formed in the floor, and an air passage connecting the indoor unit and the air outlet is formed under the floor. Thus, the air suction port can reliably suck high-temperature air accumulated in the upper space of the cubicle room into the indoor unit, and cools the cubicle.
JP-A-6-37475

However, the operation of the cooling device is frequently started and stopped to the extent that hunting occurs due to a change in heat generation in the cubicle. For this reason, in particular, troubles such as compressors frequently occur, and there is a problem that much labor is required for maintenance.
In addition, the temperature balance in a narrow cubicle is poor, and the temperature alarm of the communication base station frequently occurs on a hot day, and each time it must go to the communication base station for inspection, and it is stable as a communication base station Operation was hindered, and stable temperature control was required.
The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a cubicle capable of preventing frequent failures and performing stable temperature management in the cubicle.

In order to solve the above-mentioned problem, the invention of claim 1 is, for example, as shown in FIGS. 1 to 8, a cubicle body 1 installed outdoors as a communication base station, and a cubicle body provided in the cubicle body. A cubicle 100 comprising a wireless device 2 to which a wireless communication line M drawn from the outside of the main body to the inside is connected,
A heat exchanging device 61 that is always operated and exchanges heat in the cubicle body with air flow adjustment by a fan ;
A cooling device for forcibly cooling the interior of the cubicle body (for example, the indoor unit 51, the outdoor unit 52);
Based on the temperature inside the cubicle body, always controls so that the set temperature by the heat exchange with the air volume adjustment by the fan of the heat exchanger which is operated, set by heat exchange capacity of the heat exchange device Air-conditioning control means for operating the cooling device to perform forced cooling and controlling it to a set temperature when the temperature is exceeded,
Within the heat exchange capacity of the heat exchange device, the cooling device is held in a stopped state and only the heat exchange device is in an operating state to perform heat exchange of the air in the cubicle body only by the heat exchange device ,
Only when the temperature in the cubicle body exceeds the set temperature also due to the heat exchange capability of the heat exchange device, the cooling device is also used as a forced cooling as an operating state,
When the temperature in the cubicle body falls to the set temperature, the cooling device is held in a stopped state and returned to the operation state of only the heat exchange device.

According to the first aspect of the present invention, the heat exchange device, the cooling device, and the air conditioning control means are provided, and based on the temperature in the cubicle body, the heat exchange is performed with the air volume adjustment by the fan of the heat exchange device that is always operated. controls so that the set temperature, when it exceeds also the set temperature by the heat exchange capacity of the heat exchange device, is controlled to be the set temperature to force cooling by operating the cooling device. That is, when the temperature difference between the temperature inside the cubicle body and the set temperature is low, only the heat exchange device is driven, so that the heat inside the cubicle body is diffused and the temperature balance is stabilized. Here, when there is still a temperature difference from the set temperature and the heat exchange capacity of the heat exchange device cannot cope, forced cooling is performed by operating the cooling device. As a result, the temperature in the cubicle body can be reliably lowered to the set temperature.
Therefore, in the present invention, the heat exchange device is mainly used, and the cooling device is operated in combination only at a high temperature exceeding the heat exchange capacity, so the number of times of starting and stopping is reduced compared to the case of using only the cooling device. This can greatly reduce the power consumption. In addition to this, frequent failures can be prevented, and maintenance can be greatly reduced.

The invention of claim 2 is a cubicle according to claim 1, for example, as shown in FIGS.
The cubicle body is provided with a plurality of temperature sensors for detecting the temperature in the cubicle body,
The air conditioning control means calculates an average temperature from each temperature detected by the plurality of temperature sensors, and accompanies air volume adjustment by a fan of the heat exchange device based on the calculated average temperature and a preset temperature set in advance. Controlling forced cooling by heat exchange and operation of the cooling device .

According to the invention of claim 2, the cubicle body is provided with a plurality of temperature sensors, and the air conditioning control means calculates the average temperature from the temperatures detected by the plurality of temperature sensors, and calculates the calculated average. Based on the temperature and the set temperature, heat exchange with air volume adjustment by the fan of the heat exchange device and forced cooling by the operation of the cooling device are controlled, so the temperature sensor is installed in one place as before and one temperature Compared to the case where temperature management is performed by a sensor, temperature management can be performed at a plurality of locations. Therefore, the temperature balance in the cubicle body can be stabilized and stable temperature management can be performed. Furthermore, it is possible to improve the reliability of operation of communication equipment.

The invention of claim 3 is a cubicle according to claim 2 , for example, as shown in FIGS.
Since the plurality of temperature sensors are installed at least at the hottest place and the coldest place in the cubicle body, the temperature of the cubicle body as a whole can be reliably detected with high accuracy. Temperature management can be performed.

  According to the invention of claim 3, since the plurality of temperature sensors are respectively installed at least at the hottest place and the coldest place in the cubicle body, the temperature of the cubicle body as a whole is reliably detected. Temperature control can be performed with high accuracy.

According to the cubicle according to the present invention, the heat exchanger is mainly used, and the cooling device is operated in combination only at a high temperature exceeding the heat exchange capacity, so that the number of start and stop of the device can be greatly reduced. In addition, the power consumption can be reduced, frequent failures can be prevented, and maintenance can be greatly reduced.
In addition, since a plurality of temperature sensors are provided, stable temperature management can be performed, and reliability of operation of communication equipment can be improved.
Furthermore, the combined use of the heat exchange device and the cooling device makes it possible to greatly contribute to the heat island phenomenon because the operation of the cooling device can be suppressed to the minimum necessary, and it becomes an environment-friendly system.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 is a side view showing a state in which a wireless communication line is drawn into a cubicle body according to an embodiment of the present invention, FIG. 2 is a top sectional view of the cubicle, FIG. 3 is a front view of the interior of the cubicle, and FIG. Fig. 5 (a) is an external top view of the cubicle, (b) is an external left side view, (c) is an external front view, (d) is an external right side view, and (e) Is a rear view, FIG. 6A is a left side view of the communication base station integrated board, FIG. 7B is a front view, and FIG. 7 is a wiring diagram of power lines and wireless communication lines in the cubicle.
As shown in FIG. 1 to FIG. 6, a cubicle 100 according to the present invention is installed outdoors as a communication base station, and has a substantially box-shaped cubicle body 1, and a cubicle body 1 provided in the cubicle body 1. A wireless device 2 to which a wireless communication line M drawn from the outside to the inside is connected, and a communication base station integrated panel 3 having a plurality of auxiliary devices attached to the wireless device 2 are provided.

The cubicle body 1 is made of steel or aluminum, for example. Two front doors 11 having a double door opening are attached to the front surface of the cubicle body 1, and one similar side door 12 is attached to the right side surface.
Three radio devices 2 accommodated in the cubicle body 1 are arranged along the front plate of the cubicle body 1 including those for future expansion. A storage battery 4 is arranged on the right side of these radios 2 as an emergency power source for the radios 2. If the future expansion space is not considered, the cubicle body 1 is further downsized.

In addition, above the storage battery 4, a ceiling-mounted indoor unit 51 that generates and blows cold air or the like is installed on the top plate of the cubicle body 1, and an outdoor unit 52 that compresses refrigerant or the like is provided on the outer surface of the back plate. is set up.
In addition, a panel-shaped heat exchange device 61 is incorporated inside the back plate of the cubicle body 1, and an intake hood 62 is installed at the lower outer surface of the front plate, and an exhaust hood 63 is installed at the upper outer surface of the left side plate. Yes.

The heat exchange device 61 is always operated and performs heat exchange of air in the cubicle body 1. That is, an intake port (not shown) through which indoor air is drawn and an outlet (not shown) through which fresh outdoor air to be supplied is blown out are provided, and heat is generated when passing through the heat exchange device 61. An exchange has been made.
Further, the heat exchange device 61 has a controller (air conditioning control means) that performs drive control of the heat exchange device 61 itself and the cooling devices 51 and 52 in common. That is, an average temperature is calculated from each temperature detected by a plurality of temperature sensors (not shown) provided at predetermined locations in the cubicle body 1, and based on the calculated average temperature and a preset set temperature, The air flow of the heat exchange device 61 itself is adjusted and controlled to reach the set temperature. When the air flow adjustment by the heat exchange device 61 exceeds the set temperature, forced cooling is performed by the cooling devices 51 and 52 and the set temperature is set. It is controlled to become.

  It is preferable that the plurality of temperature sensors are respectively installed at least at the highest temperature and the lowest temperature in the cubicle body 1. Examples of the location where the temperature is high include the vicinity of a communication device such as the wireless device 2 or the communication base station integrated panel 3, and examples of the location where the temperature is low include the vicinity of the heat exchange device 61 and the indoor unit 51. . Moreover, it is preferable to provide three or more temperature sensors.

Hereinafter, the control operation of the controller of the heat exchange device 61 will be specifically described.
As shown in FIG. 8, first, each temperature detected by a plurality of temperature sensors is analyzed (step S1). That is, an average temperature is calculated from each temperature, and it is determined whether this average temperature is higher than a set temperature set in advance by the heat exchange device 61 (step S2). Here, the set temperature is preferably, for example, around the outside air temperature + 10 ° C.
If the temperature is lower than the set temperature, the fan of the heat exchanging device 61 is controlled to change the setting from “strong” to “weak” (step S3). If the temperature is higher than the set temperature in step S2, the fan of the heat exchange device 61 is controlled to change the setting of the air volume from “weak” to “strong” (step S4).
After the air volume is changed to “strong” in step S4, the average temperature is calculated again from the temperatures detected by the plurality of temperature sensors, and it is determined whether or not the average temperature is higher than the set temperature (step S5).
And when lower than preset temperature, it returns to step S3 and changes the air volume of the heat exchanger 61 from "strong" to "weak". If the temperature is still higher than the set temperature in step S5, the cooling devices 51 and 52 are started as “stop” → “operation” (step S6).
Thereafter, the cooling devices 51 and 52 are operated until the average temperature calculated from the temperatures detected by the plurality of temperature sensors is equal to or lower than the set temperature. When the average temperature is equal to or lower than the set temperature, “operation” is changed to “stop”. Switch and stop (step S7).

In this way, the heat exchange device 61 and the cooling devices 51 and 52 cool the temperature that rises due to heat generated by the communication base station integrated panel 3 and the radio 2 described later installed in the cubicle body 1, and the cubicle. Temperature management is performed to keep the inside of the main body 1 at an appropriate temperature.
The intake hood 62 and the exhaust hood 63 function as an emergency air conditioner in the event of a power failure. The fans in the hoods 62 and 63 are operated to perform ventilation.
Further, fluorescent lamps 13 are attached to the top of the cubicle body 1 for illumination in the cubicle body 1 at two locations.

  The communication base station integrated panel 3 is arranged on the left side of the radio device 2 and includes a plurality of auxiliary devices attached to the radio device 2. As the plurality of auxiliary devices, as shown in FIG. 7, an AC power receiving board 31, a rectifier 32, a DC power distribution board 33, a base station control board 34, an intermediate distribution board (IDF) 35, a transmission device 36, and the like can be cited. The plurality of incidental devices are accommodated and integrated in the accommodation rack 30 while being wired to each other.

The accommodation rack 30 has a substantially box shape, and a plurality of shelves are provided on the left side and the front. As shown in FIG. 6 (a), an operation panel provided with switches, meters, and the like of the AC power receiving panel 31, the AC power receiving panel 31 and the DC distribution board 33 in order from the bottom on the left side surface of the housing rack 30. 37, a DC distribution board 33 is accommodated, and a DC terminal block space 38a is provided above the DC distribution board 33. Thus, by accommodating the AC power receiving panel 31, the operation panel 37, and the DC distribution panel 33 on the left side surface of the storage rack 30, the operability when the front door 11 is opened is improved.
Further, as shown in FIG. 6B, a space that can be used as an inverter space 38b is provided in order from the bottom on the front side of the accommodation rack 30, and the base station control panel 34 and the rectifier 32 are accommodated in the upper part. A utility space that can be used as the AC terminal block space 38c and the DC terminal block space 38d is provided, and can flexibly cope with changes in the configuration and expandability of the communication device configuration.
Further, an intermediate switchboard 35 is accommodated on the right side of these rectifiers 32 and the like, and a plurality of auxiliary devices accommodated in the accommodation rack 30 are integrated with each other in a wired state.

  In the accommodation rack 30 shown in FIG. 6, the transmission device 36 shown in FIG. 7 and other ancillary equipment are not shown because of the drawing. It is assumed that what is shown in the integrated board for communication base stations is accommodated. For example, an indoor control unit 39b that indoors controls a control device 39a that is installed outdoors and controls the tilt angle of the antenna 17 can be used.

Hereinafter, the wiring of the wireless communication line M and the power line D drawn into the cubicle body 1 will be described with reference to FIGS. 1 and 7.
A through plate 14 having a plurality of holes through which the power line D connected to the wireless communication line M, the above-described AC power receiving panel 34 and the like is inserted is attached to the upper portion of the left side plate of the cubicle body 1. For the sake of illustration, only the wireless communication line M is shown in FIG.
The wireless communication line M attached to the antenna 17 is supported by an external cable rack 7 installed outside the cubicle body 1 and is drawn into the cubicle body 1 through a hole in the through plate 14. The wireless communication line M is connected to the ground line S via a conversion connector 16 having an arrester 18 in the vicinity of the through plate 14. The ground wire S is connected to a ground terminal in the ground box 9, and the ground box 9 is fixed to the outer surface (outer wall surface) of the left side plate of the cubicle body 1 and is integrally attached to the cubicle body 1. The grounding box 9 has conductivity such as steel or aluminum as in the cubicle body 1.
The ground wire S grounded to the ground G at the ground terminal in the ground box 9 is further drawn into the cubicle body 1 through the hole of the through plate 14. The ground line S drawn into the cubicle body 1 in this way is connected to a ground board (not shown) in the communication base station integrated board 3. A plurality of ground lines S branched by the ground board are connected to the respective radio devices 2 (see FIGS. 2 and 7).
In this way, the wireless device 2 is grounded to the ground G via the ground wire S and the ground box 9.

  Further, the wireless communication line M drawn as it is into the cubicle body 1 without being branched to the ground line S is directly connected to each wireless device 2 and has a wiring structure shown in FIG. That is, a radio wave signal received by the antenna 17 is input to each wireless device 2 through the wireless communication line M, and then transmitted to an exchange (not shown) through an optical cable via a transmission device (DSU) 36.

As shown in FIG. 7, the power line D is connected to a power security device 10 installed on the outer surface of the cubicle body 1 as necessary before being drawn into the cubicle body 1. The power security device 10 includes a lightning-proof transformer (not shown) inserted in the power line D, thereby protecting the communication base station integrated panel 3 from lightning surge caused by induced lightning. Furthermore, the protection of the communication base station integrated panel 3 by direct lightning and the influence on surrounding private houses are kept to a minimum.
The power line D is drawn into the cubicle body 1 from the hole of the through plate 14 via the power security device 10. Thereafter, the power line D drawn into the cubicle body 1 is connected to the AC power receiving board 31 in the communication base station integrated board 3, and the AC power receiving board 31 is connected to the base station control board 34. The single-phase AC100V output from the base station control panel 34 is used for fluorescent lamp illumination and outlets, and the three-phase AC200V is used for power for the cooling devices 51 and 52 and the like. On the other hand, the AC power receiving panel 31 is connected to a rectifier 32, and a DC power source from the rectifier 32 is used for the storage battery 4, the wireless device 2, the transmission device 36, and the like for supplying power to a communication device.
Further, the cubicle body 1 has a connector of the mobile power supply vehicle 19 so that power can be supplied in the event of a power failure.

The base station control panel 34 is related to the air conditioning of the heat exchange device 61 and the cooling devices 51 and 52, the temperature sensor installed in the cubicle body 1, the opening and closing of the front door 11 and the side door 12, the activation of the ventilation fan, the opening and closing of the shutter, etc. The contact points for alarm signals and control-related signals are integrated. Further, various signal contacts of the base station control panel 34, the rectifier 32, the storage battery 4, and the wireless device 2 are wired in the panel to the intermediate switchboard 35 to monitor the abnormality and operation of each device.
As monitoring items, for example, during the work in the cubicle body 1, the doors 11 and 12 are opened, the rectifier 32 is broken, the voltage of the storage battery 4 is lowered, the temperature in the cubicle body 1 is abnormal, and the fan of the heat exchange device 61 is broken. And operation / stop, failure of the cooling devices 51 and 52, fire, and the like. Specifically, the ventilation fan is activated or the shutter is opened at the time of a power failure, and the heat exchange station 61 is activated to stop the ventilation fan and close the shutter when the power failure is restored. In addition, when the doors 11 and 12 are opened and closed, the illumination of the fluorescent lamp 13 is turned ON / OFF.

As shown in FIG. 2, the wireless communication line M, each ground line S, and the power line D drawn into the cubicle body 1 as described above are installed along the upper wall surface of the cubicle body 1. The cable rack 8 is supported and wired. Here, since it is a top view in FIG. 2, it seems that the wireless communication line M, the ground line S, and the power line D are one, but in practice, a plurality of wireless communication lines M and a plurality of ground lines S are provided. And the several power line D is wired along the wall surface.
The internal cable rack 8 includes a long cable support 81 provided facing the wall surface above the wireless device 2 and the communication base station integrated panel 3 and the like, and a space between the cable support 81 and the wall surface. And a plurality of cable support fittings 82 provided so as to be orthogonal to each other. The wireless communication line M, the ground line S, and the power line D are supported by the cable support fittings 82 and wired along the wall surface. By wiring along the wall surface in this way, the flow of air in the cubicle body 1 can be made better than when wiring in the center of the cubicle body 1.

As described above, according to the cubicle 100 according to the embodiment of the present invention, since the cooling devices 51 and 52, the heat exchange device 61, the air conditioning control means, and the plurality of temperature sensors are provided, the detection is performed by the plurality of temperature sensors. The average temperature is calculated from each temperature, and if the average temperature is equal to or higher than the set temperature, the air volume of the heat exchange device 61 is set to “strong”, and the heat in the cubicle body 1 is diffused to stabilize the temperature balance. After that, if the average temperature is equal to or higher than the set temperature, the temperature in the cubicle body 1 can be reliably lowered to the set temperature by operating the cooling devices 51 and 52 for forced cooling. As described above, since the air conditioning control means shares the control of the heat exchange device 61 and the cooling devices 51 and 52 and is operated in combination, the number of times of starting and stopping can be greatly reduced, and the power consumption is reduced. As well as being able to prevent frequent failures, maintenance can be greatly reduced.
In addition, since temperature management can be performed at a plurality of locations by providing a plurality of temperature sensors, the temperature balance in the cubicle body 1 can be stabilized and stable temperature management can be performed. Furthermore, it is possible to improve the reliability of operation of communication equipment.
Further, since the plurality of temperature sensors are respectively installed at the highest temperature place and the low temperature place in the cubicle body 1, the temperature of the cubicle body 1 as a whole can be detected with certainty and accuracy. Good temperature control.

In addition, embodiment of this invention is not limited to the said embodiment, Unless it changes the summary, it can change suitably.
In the above embodiment, the heat exchange device 61 is controlled so as to reach the set temperature by adjusting the air volume, and is further controlled to be set to the set temperature by performing the forced cooling by the cooling devices 51 and 52. The controller (air conditioning control means) provided in 61 is used, but this controller may be separated from the heat exchange device 61.

  Further, in the cubicle 100, the front door 11 having a double door is used in terms of operability of the communication base station integrated panel 3, and the operation panel 37 is disposed at a position where the front door 11 is opened. As shown in FIG. 12, for indoor maintenance, the communication base station integrated panel 3 may be provided at a position away from the door 11 </ b> A, and the cubicle 100 </ b> A with the door 11 </ b> A opened as one side may be used. In this case, the cost can be reduced by using the single-open door 11A. 9-12, the same code | symbol is attached | subjected about the structure similar to FIGS. 1-6.

Moreover, as an incidental apparatus accommodated in the said accommodation rack 30, not only the incidental apparatus shown in FIG. 7 but an inverter may be put. In this case, it can be accommodated in the inverter space 38b.
Furthermore, the arrangement of a plurality of auxiliary devices such as the AC power receiving board 31, the DC power distribution board 33, the operation panel 37, and the intermediate power distribution board 35 housed in the housing rack 30 is not limited to the above-described arrangement and may be changed as appropriate. . Furthermore, the arrangement of each device such as the wireless device 2, the communication base station integrated panel 3, and the cooling devices 51 and 52 in the cubicle body 1 can be changed as appropriate.

FIG. 3 is a side view illustrating a state in which a wireless communication line is drawn into the cubicle body for illustrating the embodiment of the present invention. FIG. 2 is a top sectional view of the cubicle. FIG. 2 is a front view showing the interior of the cubicle. FIG. 3 is a right side view showing the interior of the cubicle. 4A is a top view showing the appearance of the cubicle, FIG. 3B is a left side view, FIG. 3C is a front view, FIG. 3D is a right side view, and FIG. (A) is a left side view of the communication base station integrated panel, and (b) is a front view. FIG. 3 is a wiring diagram of a power line and a wireless communication line in the cubicle. It is a flowchart which shows operation | movement of a heat exchange apparatus similarly. It is for showing the modification of this invention, and is a top sectional view of a cubicle. FIG. 2 is a front view showing the interior of the cubicle. FIG. 3 is a right side view showing the interior of the cubicle. 4A is a top view showing the appearance of the cubicle, FIG. 3B is a left side view, FIG. 3C is a front view, FIG. 3D is a right side view, and FIG.

Explanation of symbols

1 Cubicle body 2 Radio 51 Indoor unit (cooling device)
52 Outdoor unit (cooling system)
61 Heat Exchanger 100 Cubicle M Wireless Communication Line

Claims (3)

A cubicle body (1) installed outdoors as a communication base station, and a radio (2) provided in the cubicle body and connected to a wireless communication line (M) drawn from the outside to the inside of the cubicle body. A cubicle (100) comprising:
A heat exchanging device (61) that is always operated and exchanges heat in the cubicle body with air volume adjustment by a fan ;
A cooling device (51, 52) for forcibly cooling the interior of the cubicle body;
Based on the temperature inside the cubicle body, always controls so that the set temperature by the heat exchange with the air volume adjustment by the fan of the heat exchanger which is operated, set by heat exchange capacity of the heat exchange device Air-conditioning control means for operating the cooling device to perform forced cooling and controlling it to a set temperature when the temperature is exceeded,
Within the heat exchange capacity of the heat exchange device, the cooling device is held in a stopped state and only the heat exchange device is in an operating state to perform heat exchange of the air in the cubicle body only by the heat exchange device ,
Only when the temperature in the cubicle body exceeds the set temperature also due to the heat exchange capability of the heat exchange device, the cooling device is also used as a forced cooling as an operating state,
The cubicle characterized in that when the temperature in the cubicle body falls to the set temperature, the cooling device is held in a stopped state and returned to the operation state of only the heat exchange device. The cubicle body is provided with a plurality of temperature sensors for detecting the temperature in the cubicle body,
The air conditioning control means calculates an average temperature from each temperature detected by the plurality of temperature sensors, and accompanies air volume adjustment by a fan of the heat exchange device based on the calculated average temperature and a preset temperature set in advance. The cubicle according to claim 1, wherein forced cooling by controlling heat exchange and operation of the cooling device is controlled .   3. The cubicle according to claim 2, wherein the plurality of temperature sensors are respectively installed at least at a location having the highest temperature and a location having the lowest temperature in the cubicle body.

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