JP2019146395A - Facility for high-voltage power reception - Google Patents

Abstract

To provide a place where a plurality of operation modules can be installed in a box of a facility for high-voltage power reception.SOLUTION: A facility 1 for high-voltage power reception is provided with power reception and distribution devices inside a box 11, and is constituted by installing a module panel 3 with a plurality of operation modules with which sensors are connected provided inside or outside the box facing an opening 13 of the box.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a high-voltage power receiving facility.

  A high-voltage power receiving facility called a cubicle is known. As understood from the description in Patent Document 1, it is also known to use a sensor attached to a high-voltage power receiving facility. When a sensor is attached to a high-voltage power receiving facility, it may be necessary to attach an arithmetic module that is a set with the sensor. In this case, if a large number of types of sensors are attached, a large number of corresponding calculation modules are required. In addition, when data is to be transmitted to the outside, a separate module may be required for communication.

JP 2006-120656 A

  By the way, the high-voltage power receiving facility has a space necessary for inspection and the like, and a space where other devices cannot be installed due to the arrangement of the high-voltage devices. When the types of arithmetic modules and the like increase, it is necessary to secure a place for installing them. However, when they are arranged separately, wiring work and power supply securing work become troublesome.

  The inventor of the present case tried to solve the problem by diligently examining this point. An object of the present invention is to provide a place where a plurality of arithmetic modules can be installed in a box of a high-voltage power receiving facility.

  In order to solve the above problems, a high-voltage power receiving facility provided with power receiving and distributing equipment inside a box, and a module panel including a plurality of arithmetic modules connected to sensors provided inside or outside the box is provided with an opening of the box. It will be a high-voltage power receiving facility installed facing the front.

  Further, it is preferable to arrange the module panel so as to be aligned with the breaker group.

  Moreover, it is preferable that the module panel includes a power supply unit connected to the arithmetic module.

  Further, it is preferable that a transformer is provided inside the box, and the module panel is installed in a space between the transformer and the door.

  Further, it is preferable that a high voltage switch is provided inside the box, and the module panel is installed so that the high voltage switch is exposed in a front view.

  In the present invention, it is possible to provide a place where a plurality of arithmetic modules can be installed in the box of the high-voltage power receiving facility.

It is a front view of the equipment for high voltage electric power reception which installed the module panel of the one support type on the breaker group in the box of one door. It is a perspective view of the equipment for high voltage electric power reception which installed the module panel of the one support type on the breaker group in the box of one door. It is sectional drawing of the equipment for high voltage | pressure electricity reception which installed the module panel of the one support type side by side on the breaker group in the box of one door. However, the door is omitted. Moreover, the site | part ahead of a trans | transformer is shown with the broken line and the arrow. It is a front view of the equipment for high voltage electric power reception which installed the module panel of both support types in the box of one door side by side under the breaker group. However, the door is omitted. It is sectional drawing of the high voltage | pressure power receiving equipment which installed the module panel of the both support types in the one door box side by side under the breaker group. However, the door is omitted. Moreover, the site | part ahead of a trans | transformer is shown with the broken line and the arrow. FIG. 5 is a front view of a both-support type module panel attached to the high-voltage power receiving facility shown in FIG. 4 and the like. It is a front view of the equipment for high voltage electric power reception which installed the module panel of the both support types side by side under the breaker group in the box provided with a double door. However, the door is omitted. It is sectional drawing of the equipment for high voltage | pressure electricity reception which installed the module panel of the both support types side by side under the breaker group in the box provided with a double door. However, the door is omitted. Moreover, the site | part ahead of a trans | transformer is shown with the broken line and the arrow.

  The form for implementing this invention is shown below. The high-voltage power receiving facility 1 according to the present embodiment includes a power receiving / distributing device inside the box 11, and the module panel 3 including a plurality of calculation modules connected to sensors provided inside or outside the box 11. It is installed facing the opening 13. For this reason, it becomes possible to provide a place where a plurality of arithmetic modules can be installed in the box 11 of the high-voltage power receiving facility 1. The module panel 3 is fixed to equipment mounting rails 20 arranged vertically on both sides of the opening 13 of the box 11.

  Inside the box 11, a transformer 14, a high-voltage switch 19, a circuit breaker, and the like are installed as power receiving and distribution equipment. Examples of the high-voltage switch 19 include a high-voltage load switch (LBS), a high-voltage circuit breaker (CB), and a disconnecting switch (DS), which are regularly inspected.

  As will be understood from FIGS. 1 to 3 and the like, the high-voltage power receiving facility 1 according to the embodiment includes a transformer 14 (transformer) used for converting high-voltage electricity sent through a transmission line. It is provided in the lower part in the box 11. Electricity is stepped down by this transformer 14 and sent to each destination. In the examples shown in FIGS. 1 to 5, the transformer 14 can be used for both electric lamps and power. However, a transformer for electric lamps and a transformer for power can be provided separately.

  The high-voltage power receiving facility 1 of the embodiment can collect and arrange a plurality of arithmetic modules by installing the module panel 3 in the box 11. Since the module panel 3 of the embodiment is installed facing the opening 13 of the box 11, the module panel 3 cannot be visually recognized when the door 12 used to close the opening 13 is closed. On the other hand, when the door 12 is opened, the surface side of the module panel 3 becomes visible. Further, when the door 12 is open, the arithmetic module installed on the module panel 3 can be easily approached, and inspection work and replacement work can be performed smoothly. In addition, by providing a window at a position corresponding to the module panel 3 with respect to the door 12, the module panel 3 may be visible even when the door 12 is closed.

  A plurality of calculation modules are arranged on the front side of the module panel 3 of the embodiment. The module panel 3 includes an arithmetic module capable of numerically converting the measurement signals of the sensors arranged inside and / or outside the box 11. The arithmetic module may be a microserver 54 or the like, or may be a sensor and an arithmetic module that are configured integrally, such as an earthquake sensor 56.

  In the example shown in FIGS. 1 to 3, the module panel 3 is a single-support type in which the left side is supported, but as shown in FIGS. 4 and 5, the dual-support type in which the left and right sides are supported. The module panel 3 may be used. In this case, as shown in FIG. 6, the number of devices mounted on the module panel 3 can be easily increased. In the example shown in FIGS. 1 to 3, the module panel 3 is provided with the earth leakage fire alarm 51 and the wattmeter 52 that are arithmetic modules. However, the insulation monitoring device 53 that is the arithmetic module is attached to the door 12. Yes. On the other hand, in the example shown in FIG. 6, the module panel 3 includes a leakage fire alarm 51, a wattmeter 52, an insulation monitoring device 53, a micro server 54, an environmental sensor module 55, and an earthquake sensor 56 that are arithmetic modules.

  The module panel 3 is preferably arranged in front of the transformer 14. If the module panel 3 is arranged between the transformer 14 arranged at the lower part of the high-voltage power receiving facility 1 and the door 12, the module panel 3 is obstructed when the high-voltage switch 19 provided at the upper part of the high-voltage power receiving facility 1 is inspected. Can be avoided. When the module panel 3 is installed in the vicinity of the high-voltage switch 19, it is preferable to install the module panel 3 so that the high-voltage switch 19 is exposed when the high-voltage power receiving facility 1 is viewed from the front. That is, it is preferable to install the module panel 3 so as to leave a desired space in the high voltage switch 19 from the opening 13 of the box 11. In other words, it is preferable to install the module panel 3 around the high-voltage switch 19 when viewed from the front. The high-voltage switch 19 may be opened and closed during regular inspection work, but if installed in this way, the module panel 3 can be prevented from becoming an obstacle to the inspection work. In addition, it is preferable to install the module panel 3 in the space between the transformer 14 and the door 12 because a sufficient distance can be ensured between the transformer 14 and the high-voltage switch 19 and safety during inspection can be ensured. In the periodic inspection, maintenance such as retightening of the wiring connection is performed. Of course, it is preferable to mount the module panel 3 at a position that does not hinder the operation of the device such as a switch or a circuit breaker. Since the power strip of the transformer 14 may be changed when the high-voltage power receiving facility 1 is installed, it is preferable to attach the module panel 3 while avoiding the upper portion of the transformer 14 when the high-voltage power receiving facility 1 is viewed from the front. .

  In the example shown in FIGS. 1 to 5, the module panel 3 is arranged in front of the transformer 14. Among these, in the example shown in FIGS. 4 and 5, the module panel 3 is positioned between the transformer 14 and the door 12. In particular, in the case of the box 11 including the front double door 12, it is preferable to arrange the module panel 3 between the power transformer 14 and the door 12. In addition, in the case of the box 11 provided with the door 12 of the front double door, as shown in FIG.7 and FIG.8, it becomes the box 11 long in the left-right direction compared with the box 11 of the single door 12 shown to FIG. In the example shown in FIG. 7, the power transformer 14 is arranged on the lower right side, but an electric transformer (not shown) is arranged on the lower left side. The space between the transformer 14 and the door 12 includes the back surface of the door 12. Further, as shown in FIG. 1, some arithmetic modules (insulation monitoring device 53 in the illustrated example) may be separated from the module panel 3 and installed on the back surface of the door 12.

  Further, the module panel 3 can be disposed between the three-phase breaker disposed on the front side of the transformer 14 and the single-phase breaker disposed on the lower side of the three-phase breaker. It is preferable to arrange the module panel 3 so as to line up with the breaker group 61 formed by gathering three-phase breakers and / or single-phase breakers. 1 to 3, the module panel 3 is arranged so as to be arranged on the upper side of the breaker group 61. 4 and 5 and FIGS. 7 and 8, the module panel 3 is arranged so as to be arranged below the breaker group 61.

  In the embodiment, the three-phase breaker and the single-phase breaker are each fixed to the breaker mounting rail 62 disposed on the front side of the transformer 14, but the module panel 3 of the embodiment is fixed to the breaker mounting rail 62. Is done. For this reason, the back surface of the module panel 3 is provided with a mounting portion used for fixing to the breaker mounting rail 62. The module panel 3 may also be used as the breaker mounting rail 62.

  Examples of sensors attached to the outside of the box 11 include a sunshine meter, a thermometer, a hygrometer, and a rain gauge. A meteorometer 91 in which a plurality of such items are collected may be attached to the outside of the box 11. These are connected to the environmental sensor module 55 which is one of the arithmetic modules, and the environmental sensor module 55 converts the measurement signal into a numerical value.

  Examples of the sensor attached to the inside of the box 11 include an insulation sensor, an ammeter, a voltmeter, a thermometer, a cutoff signal, and a door open / close signal. In the embodiment, the insulation sensor is connected to the insulation monitoring device 53, which is an arithmetic module, and is used to detect partial discharge. An ammeter, a voltmeter, a cutoff signal, and a door opening / closing signal are used by being connected to a microserver 54 that is an arithmetic module. The thermometer is used by being connected to an environmental sensor module 55 which is an arithmetic module.

  On the surface of the module panel 3 of the embodiment, an arithmetic module, a power supply unit, and a circuit breaker 81 are provided. Electricity necessary for operating the arithmetic module can be provided from the power supply unit. What is necessary is just to use the outlet 71, the power supply terminal block 72, etc. as a power supply part. In the case of the outlet 71, an outlet bar having a plurality of insertion openings may be used. Thus, by providing the module panel 3 with the power supply unit that is connected to the arithmetic module, it is possible to reduce the labor of wiring. Note that the power supply unit may be able to supply power other than the arithmetic module fixed to the module panel 3. For example, electricity used for the earthquake sensor 56 installed on the bottom surface of the box 11 may be provided from a power supply unit fixed to the module panel 3.

  The arithmetic module may acquire a sensor measurement signal from a signal line connected to the signal terminal block. In this case, if the signal terminal block is fixed to the surface of the module panel 3, it is possible to suppress the complicated connection between the arithmetic module and the sensor. The signal lines between the arithmetic modules may be stored in a duct or the like provided on the module panel 3. If the signal terminal block is fixed on the surface of the module panel 3, the sensor wiring can be concentrated on the signal terminal block of the module panel 3, so that the wiring of the sensor or the like does not get in the way during inspection. . For this reason, workability | operativity can be improved.

  Data converted by the calculation module may be collected in the microserver 54. In this case, the information collected in the microserver 54 may be output to the outside. For this reason, the antenna 82 may be connected to the microserver 54.

  Here, an example of the flow from the shipment of the high-voltage power receiving facility 1 including the module panel 3 to the wiring will be briefly described. First, each sensor fixed in the box 11 is attached at the factory shipment stage. The high-voltage power receiving facility 1 in this state is transported to the installation location, and a sensor fixed outside the box 11 is installed at the installation site. Thereafter, the module panel 3 is fixed and wiring is completed. Of course, it is not necessary to perform the operations in this order, and appropriate operations may be performed as appropriate.

  As described above, the present invention has been described by taking the embodiment as an example. However, the present invention is not limited to the above-described embodiment, and various aspects can be adopted. For example, it is possible to arrange a module panel between the electric transformer and the door.

DESCRIPTION OF SYMBOLS 1 High voltage power receiving equipment 3 Module panel 11 Box 12 Door 13 Opening 14 Transformer 61 Breaker group

Claims (5)

  A high-voltage power receiving facility with power distribution equipment inside the box, with a high-voltage module panel equipped with a plurality of calculation modules connected to sensors inside or outside the box facing the opening of the box Power receiving equipment.   The high-voltage power receiving facility according to claim 1, wherein module panels are arranged so as to line up with the breaker group.   The high-voltage power receiving facility according to claim 1 or 2, wherein the module panel includes a power supply unit connected to the arithmetic module.   The high-voltage power receiving facility according to claim 1, further comprising a transformer inside the box, wherein the module panel is installed in a space between the transformer and the door.   The high-voltage power receiving facility according to claim 1, further comprising a high-voltage switch inside the box, wherein the module panel is installed so that the high-voltage switch is exposed in a front view.