JP6706168B2 - Power system - Google Patents

Description

The present invention relates to a rack in which a plurality of electric devices can be installed, and a power supply system configured by installing a plurality of power supply devices in the rack.

There have been many racks for electric equipment in which a plurality of electric equipment can be installed (for example, see Patent Document 1). Each of the plurality of electric devices installed in the rack is usually connected to a repeater such as a breaker or an outlet used for connection with a power supply source (for example, a commercial power supply) via a power transmission cable.

JP, 2005-133345, A

However, in the conventional rack for electric equipment, as the number of electric equipment installed in the rack increases, it becomes necessary to pass more power transmission cables between the rack and the repeater, and therefore, in a facility such as a factory. There is a problem that the wiring of the power transmission cable in the above becomes complicated.

Then, the objective of this invention is providing the rack for electric equipment which can simplify wiring of a power transmission cable, and the power supply system comprised using the said rack.

The rack for electric equipment according to the present invention includes a rack portion, a bus bar, and a storage portion. The rack portion is configured by providing a plurality of installation shelves in which electric devices are installed in the height direction. The bus bar is common to the plurality of electric devices installed on each of the plurality of installation shelves and extends in the height direction. The storage section has a bus bar stored and fixed therein, and is rotatably attached to the rack section.

According to the electrical equipment rack, after the power supply device is installed on each of the installation shelves, the connection terminal provided on the power supply device and the bus bar are connected via a short power transmission cable with the storage unit opened. Can be easily connected. Therefore, the connection work performed by the user is simplified, and as a result, workability is improved. Further, only one power transmission cable corresponding to the bus bar is required to connect the bus bar to the repeater such as a breaker or an outlet. That is, it is not necessary to connect the power transmission cable to the repeater for each power supply device, and the number of wires from the rack for electrical equipment to the repeater is reduced.

According to the present invention, it is possible to simplify the wiring of the power transmission cable.

It is the perspective view which looked at the power supply system concerning the embodiment of the present invention from the front side. It is the perspective view which looked at the power supply system from the back side. (A) It is the perspective view which showed the power supply device with which the (B) power supply system was seen, respectively from the front side and the back side. It is the perspective view which showed the rack for electric equipment. FIG. 6 is a plan view showing an opened/closed state of a storage unit included in the rack for electric devices. It is the perspective view which showed the power supply system by which the storage part was arrange|positioned at the closed position seen from the back side. It is a perspective view showing a connected state of a power supply unit and an input bus bar.

1 and 2 are perspective views showing a power supply system according to an embodiment of the present invention as viewed from the front side and the back side, respectively. As shown in FIGS. 1 and 2, the power supply system includes six power supply devices 1 that are electric devices, and an electric device rack 2 in which these are installed. The electric equipment rack 2 may be one in which a plurality of power supply devices 1 that are not limited to six can be installed.

3A and 3B are perspective views showing the power supply device 1 as viewed from the front side and the back side, respectively. As shown in FIGS. 3A and 3B, each of the power supply devices 1 includes a box-shaped housing 11 and a power supply circuit (not shown) built in the housing 11. Prepare In the present embodiment, the power supply circuit is a circuit that converts a three-phase (R-phase, S-phase, T-phase) AC voltage into a DC voltage, and an electronic component (such as a switching element) that requires cooling, such as a smoothing circuit or a converter circuit. It contains a built-in circuit.

In order to enable cooling of the power supply circuit, an intake port 11a is provided on the front wall 11A (front side wall) of the housing 11 (see FIG. 3A), and the rear wall 11B (back side) of the housing 11 is provided. The exhaust port 11b is provided on the wall (see FIG. 3B). Then, by driving a blower (not shown) such as a fan, the cooling air flows into the housing 11 from the intake port 11a, passes through the housing 11 and is exhausted from the exhaust port 11b. Therefore, it is preferable that the intake port 11a and the exhaust port 11b are maintained in an open state without being blocked by the storage section 23 and the like described later.

In the present embodiment, on the rear wall 11B of the power supply device 1, three input terminals (R-phase terminal 12r, S-phase terminal 12s, T-phase terminal 12t) for inputting a three-phase AC voltage to the power supply device 1, A ground terminal 12e and two output terminals (a positive electrode terminal 13p and a negative electrode terminal 13q) for outputting a DC voltage from the power supply device 1 are provided. Since the three-phase AC voltage from the commercial power source is input to the input terminal, a high voltage is applied, while the current flowing at this time is suppressed to be small. On the other hand, at the output terminal, the output voltage is suppressed low, while the current flowing at this time becomes large.

In the power supply system, the input of the three-phase AC voltage to the six power supply devices 1 is performed through the three input bus bars (R-phase bus bar 22r, S-phase bus bar 22s, T-phase bus bar 22t) common to these power supply devices 1. (See FIG. 2). The outputs of the DC voltage from the six power supply devices 1 are collectively taken out by the two output bus bars (the positive electrode bus bar 32p and the negative electrode bus bar 32q) common to these power supply devices 1 (see FIG. 2). Therefore, the current taken out becomes large. Then, the output from the power supply system is used as a power supply for the plating apparatus, for example.

In an environment where the plating process is performed, the plating solution is easily scattered. For this reason, especially the input terminal to which a high voltage is applied needs to be protected from the deposition of the splashed plating solution. The configuration for protecting the input terminal will be described later.

FIG. 4 is a perspective view showing the rack 2 for electric equipment. As shown in FIG. 4, the rack 2 for electrical equipment includes a rack portion 21, three input bus bars (R-phase bus bar 22r, S-phase bus bar 22s, T-phase bus bar 22t), a ground bus bar 22e, and a storage portion. And 23.

The rack portion 21 is configured by providing six installation shelves 211 on which the power supply device 1 is installed in the height direction Dt. Specifically, the rack unit 21 is configured to hold the entire installation shelf 211 with four columns 212. The configuration of the rack portion 21 is not limited to this, and various modifications are possible. For example, the rack unit 21 may be composed of a plurality of installation shelves 211 that are not limited to six.

As described above, in each of the power supply devices 1, the intake port 11a and the exhaust port 11b are preferably maintained in an open state without being blocked. Therefore, as shown in FIG. 4, the rack portion 21 is preferably open on the suction side and the discharge side (front side and back side of the rack portion 21) of the cooling air for cooling the power supply device 1.

The R-phase bus bar 22r is common to the R-phase terminals 12r provided in the six power supply devices 1 and extends in the height direction Dt. The S-phase bus bar 22s is common to the S-phase terminals 12s provided on the six power supply devices 1 and extends in the height direction Dt. The T-phase bus bar 22t is common to the T-phase terminals 12t provided on the six power supply devices 1 and extends in the height direction Dt. The grounding bus bar 22e is common to the grounding terminals 12e provided in the six power supply devices 1 and extends in the height direction Dt. The four bus bars are housed and fixed in the housing portion 23 in a state of being arranged in parallel.

The storage portion 23 has a box shape having an opening 23a that expands in the height direction Dt, and the four bus bars stored and fixed in the storage portion 23 face the outside from the opening 23a.

The storage section 23 is rotatably attached to the rack section 21 so that the storage section 23 can be opened and closed as follows. FIG. 5 is a plan view showing the opened/closed state of the storage section 23. Note that the top wall of the rack portion 21 is not shown in FIG. As shown in FIG. 5, the storage section 23 has a closed position P1 (see FIG. 6) close to the installation shelf 211 with the opening 23a facing the inside of the rack section 21, and the opening 23a has the installation shelf 211. It is attached to the rack portion 21 so as to be rotatable between an open position P2 (see FIG. 2) which is separated from.

Specifically, as shown in FIG. 4, the upper part of one of the two columns 212 supporting the rear side of the four columns 212 (in the present embodiment, the column 212 on the right rear side in FIG. 4). An L-shaped metal fitting 213 is attached to each of the lower part and the lower part, and the housing portion 23 is axially supported by the screw 214 with respect to the metal fitting 213. That is, the storage portion 23 is axially supported by the rack portion 21 such that the direction of the central axis 23b of rotation is the height direction Dt.

More specifically, the storage section 23 is pivotally supported so that it can be opened and closed as follows. When the storage section 23 reaches from the closed position P1 to the open position P2, one of the side surfaces of the storage section 23, which is closer to the central axis 23b, comes into contact with the support column 212 of the rack section 21, thereby rotating the storage section 23. Stop. Such an opening/closing operation allows the opening/closing angle of the storage section 23 to be 90° or more (see FIG. 5). Therefore, by setting the opening/closing angle to a large value of 90° or more, it is possible to open the storage portion 23 largely even if the space is small, and as a result, the user who performs the wiring work or the like can move the power supply device 1 to the rear side. It becomes easy to put in a hand, and it becomes easy to visually recognize the work surface (for example, the back surface of the power supply device 1 or the opening 23a of the storage 23).

In the present embodiment, the storage portion 23, when arranged in the closed position P1, directs the opening 23a toward the rear wall 11B of the power supply device 1 and removes all the input terminals and the ground terminals provided in the six power supply devices 1. The position pivotally supported by the rack portion 21 is set so as to be in the covered state (see FIG. 6). Therefore, when the storage section 23 is opened from the closed position P1 (particularly when it is arranged in the open position P2), all the input terminals and the ground terminals are exposed to the outside. In the present embodiment, the storage section 23 can be fixed to the rack section 21 with the fixing screw 215 while being arranged in the closed position P1.

Furthermore, the storage portion 23 does not interfere with the flow path of the cooling air discharged from the exhaust port 11b at any position between the closed position P1 and the open position P2 so that the flow path is not blocked. It is preferable to avoid the mounting (see FIGS. 2 and 6). As a result, it is possible to prevent a decrease in cooling efficiency due to the mounting of the storage section 23.

FIG. 7 is a perspective view showing a connection state between the power supply device 1 and the input bus bar. As shown in FIG. 7, according to the electrical equipment rack 2 described above, after the power supply device 1 is installed on each of the installation shelves 211, the input terminal (R phase) is opened with the storage 23 opened from the closed position P1. The terminal 12r, the S-phase terminal 12s, the T-phase terminal 12t) and the corresponding input bus bar (R-phase bus bar 22r, S-phase bus bar 22s, T-phase bus bar 22t) can be easily connected via the short power transmission cable 41. can do. At this time, similarly, the ground terminal 12e and the ground bus bar 22e can be connected via the short power transmission cable 42. Therefore, the connection work performed by the user is simplified, and as a result, workability is improved. The lengths of the power transmission cables 41 and 42 may be any length as long as they do not hinder the opening and closing of the storage section 23.

In addition, the input busbars (R-phase busbar 22r, S-phase busbar 22s, T-phase busbar 22t) and the grounding busbar 22e are connected to a repeater such as a breaker or an outlet, and four power transmission lines corresponding to those busbars are connected. Only a cable is needed. That is, it is not necessary to connect four power transmission cables to each repeater for each power supply device 1, and the number of wires from the electrical equipment rack 2 to the repeater is reduced. Therefore, the wiring of the power transmission cable to the repeater is simplified, and as a result, the wiring of the power transmission cable in a facility such as a factory is unlikely to be complicated.

In this embodiment, through holes 231a and 231b for passing a power transmission cable are provided on the upper surface and the lower surface of the storage section 23, respectively (see FIG. 4). Then, the four power transmission cables connected to the repeater are passed through either the through holes 231a or 231b depending on the place where the power supply system is installed and the situation (environment etc.). Of the through holes 231a and 231b, the through holes that are not used for inserting the power transmission cable are preferably covered with a lid that closes the through holes.

Further, according to the electrical equipment rack 2 described above, the input bus bar (R-phase bus bar 22r, S-phase bus bar 22s, T-phase bus bar 22t) and the grounding bus bar 22e are housed and fixed in the housing unit 23, and the housing unit is also housed. By closing 23 (closed position P1), all of the input terminals (R-phase terminal 12r, S-phase terminal 12s, T-phase terminal 12t) and the ground terminal 12e are covered with the storage section 23. Therefore, when the constructed power supply system is used, the connection part on the input side to which a high voltage is applied is protected. Here, to protect the connection part, protection from electric shock caused by the user touching the connection part and protection from corrosion of the plating solution splashed in the environment where the plating process is performed Is included. It is preferable to prevent the plating solution from adhering to the connection portion because it may cause an electrical short circuit. Further, corrosion of the connection portion may cause poor contact, and therefore it is preferable to prevent it.

Furthermore, the storage section 23 is pivotally supported by the rack section 21 such that the direction of the central axis of rotation 23b is the height direction Dt. Therefore, the space required for rotating the storage portion 23 can be small. The storage section 23 is attached to the rack section 21 on the cooling air discharge side while avoiding the flow path of the cooling air. Here, when the electric equipment rack 2 is installed in a facility such as a factory, it is necessary to provide a space for passing the cooling air on the discharge side of the cooling air. Under such restrictions, according to the electrical equipment rack 2 described above, the storage space 23 can be rotated by effectively utilizing the small space required for installation. Further, by setting the opening/closing angle of the storage section 23 to 90° or more, it becomes easy for the user to visually recognize the work surface, and as a result, workability is improved even in a situation where the space is limited. Will be done.

Depending on the installation location of the electrical equipment rack 2 in the facility, the storage section 23 may be attached to the rack section 21 such that the direction of the central axis of rotation is horizontal.

The configuration of each part of the electrical equipment rack 2 described above can be applied to a rack in which various electrical equipments, not limited to the power supply device 1, are installed. Further, the input bus bar described above is not limited to being connected to the input terminal of an electric device, but can be applied to various connection terminals provided in the electric device. Further, the position at which the storage portion 23 is pivotally supported is not limited to the support column 212, and can be changed as appropriate according to the position of the connection terminal of the electric device when the electric device is installed in the rack portion 21. is there.

The description of the above embodiments is to be considered as illustrative in all points and not restrictive. The scope of the invention is indicated by the claims rather than the embodiments described above. Further, the scope of the present invention is intended to include meanings equivalent to the claims and all modifications within the scope.

DESCRIPTION OF SYMBOLS 1 power supply device 2 rack 11 for electric equipment 11 case 11A front wall 11B rear wall 11a intake port 11b exhaust port 12e earth terminal 12r R phase terminal 12s S phase terminal 12t T phase terminal 13p positive electrode terminal 13q negative electrode terminal 21 rack part 22e for earth Bus bar 22r R-phase bus bar 22s S-phase bus bar 22t T-phase bus bar 23 Storage section 23a Opening section 23b Central axis 32p Positive electrode bus bar 32q Negative electrode bus bar 41, 42 Transmission cable Dt Height direction P1 Closed position P2 Open position 211 Installation shelf 212 Support 213 Metal fittings 214 screw 215 fixing screw 231a, 231b through hole

Claims (5)

A rack for electrical equipment having a plurality of installation shelves,
A plurality of power supply devices respectively installed on the plurality of installation shelves,
Equipped with
Racks for electrical equipment
The installation shelf, a rack portion provided in plurality in the height direction,
Be common to the power supply multiple, and a bus bar extending in height direction,
A storage unit in which the bus bar is stored and fixed, and is rotatably attached to the rack unit,
Have
A power supply system in which a connection terminal of each of the plurality of power supply devices and the bus bar are electrically connected to each other via a power transmission cable . The power supply system according to claim 1, wherein the storage section is axially supported by the rack section such that the direction of the central axis of rotation is the height direction. The storage portion has a box shape having an opening that extends in the height direction,
The storage section is rotatable between a closed position in which the opening section faces the inside of the rack section and is close to the installation shelf, and an opening position in which the opening section is separated from the installation shelf. The power supply system according to claim 1 or 2. The rack portion is open on the discharge side of cooling air for cooling the power supply device ,
The power supply system according to claim 1, wherein the storage section is attached to the rack section on a discharge side of the cooling air while avoiding a flow path of the cooling air. The power supply system according to claim 1, wherein the rack unit is configured to hold all of the installation shelves with a plurality of columns.

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