JP5338926B2 - Control center - Google Patents

Description

  The present invention relates to a control center that opens / closes, protects, monitors, and controls a motor connected to a low-voltage distribution circuit, and more particularly to a wiring structure that connects functional units housed in the panel to a power supply side and a load side.

  As is well known, the control center mentioned above is equipped with drawer-type functional units equipped with circuit breakers, monitoring and control devices, display units, etc. arranged in the upper and lower stages in the stand-alone cabinet panel. The main circuit of each functional unit is connected to the power supply side bus laid at the rear of the cabinet and the load connection terminal block arranged in the panel.

  The drawer-type functional unit is equipped with a unit door and a latch mechanism that locks the functional unit to the “connection position” and “disconnection position”. The unit door / circuit breaker / latch The mechanisms are mechanically interlocked to ensure safe operation and handling.

The interlock function required for the functional unit is as follows.
・ The unit door can be opened and closed only when the circuit breaker is OFF. When the unit door is ON, the door is prevented from being opened. When the unit door is open, the operation handle of the circuit breaker cannot be turned ON. .
-In addition, when the circuit breaker is in the ON state, the latch mechanism is locked and the function unit is prevented from moving in the panel.
・ In addition, during an emergency inspection of the panel, the unit door can be forcibly removed to allow the door to be opened even when the circuit breaker is on.

On the other hand, the functional units installed in the control center panel are thinned as a vertical type (circuit breaker and display unit are arranged one above the other), and are arranged in the upper and lower stages to save space in the panel. A control center in which the above-described vertical functional units are mounted side by side inside a unit storage frame arranged in a panel of a self-standing cabinet has been commercialized. In this product, each functional unit is equipped with an automatically connected power supply side contact (grip-type contact plug) on the back of the functional unit, and the functional unit is pushed into the “connection position” in the panel. An automatic connection method is adopted in which the contact is connected to the power source side bus bar (bar conductor) installed at the rear of the cabinet. On the other hand, with respect to the load-side wiring structure, a load connection terminal block is incorporated in the functional unit, and a wiring cable is manually coupled (screw tightened) to the terminal block to be connected to the load line.

In addition, as described above, in the control center where the vertical functional units are mounted side by side on the unit storage frame in the panel, each functional unit is equipped with its unit door / circuit breaker operation handle / unit, An interlock mechanism that links the latch mechanisms that are locked and locked at the disconnection position has been previously proposed by the same applicant as the present invention (see Patent Document 1).
JP 2006-33988 A

  By the way, the control center having the above-described conventional configuration has the following problems to be solved. In other words, with regard to the main circuit wiring structure of the functional unit mounted in the panel, the conventional product adopts an automatic connection method on the power supply side and a manual connection method on the load side, and is screwed to the terminal block. As a user request, there are many requests for an automatic coupling method that does not require screw tightening on the load side.

  In this regard, an automatic connection type load side contact (plug) is provided on the back of the functional unit, a contact socket corresponding to each functional unit on the back of the unit storage frame facing the load side contact, and the contact socket If a load-side terminal block to be connected to is arranged, it is necessary to secure a large wiring space in the depth direction in the panel, so that it is difficult to cope with a cabinet having the same external size as the conventional one.

  The present invention has been made in view of the above points, and provides an improved wiring structure so that the main circuit of the functional unit can be automatically connected to the power supply side and the load side without increasing the required space in the panel. Objective.

In order to achieve the above object, according to the present invention, a plurality of units comprising a circuit breaker and an assembly of monitoring and control devices are arranged inside a unit storage frame arranged in a vertical stage in a stand of a self-standing cabinet. In the control center where the drawer type functional units are mounted side by side, and the main circuit of each functional unit is connected to the power bus on the cabinet panel and the load connection terminal block,
For each of the functional units, automatic connection type power supply side and load side contacts are arranged on the back surface thereof, and the power supply side contacts are laid behind the inside of the panel on the back surface of the unit storage frame so as to face these contacts. shall place the relay contact unit is connected to the vertical generatrices of the power supply side, and a contact socket that connects to a load connection terminal block in the panel load-side contact, the unit housing frame, corresponding to the power-side contact and the individual A square hole leading to the relay contact unit is opened, and the power source side contact is automatically connected to the relay contact unit through the square hole. For each unit storage frame at the upper and lower stages, a functional unit mounted in the frame is provided. A corresponding load connection terminal block is arranged on the side of the frame.

  Further, in the above configuration, the relay contact unit includes a contact plug that connects each phase vertical bus on the power supply side, and a horizontal bus that is laid along the back of the functional unit arranged on the left and right side of the contact plug. It consists of an assembly.

  By adopting the above wiring structure, the main circuit for the vertical function unit mounted side by side in the unit housing frame in the cabinet board of the same external size as before without increasing the depth space in the board. Automatic concatenation can be achieved.

  Hereinafter, embodiments of the present invention will be described based on the illustrated examples. 1A and 1B are a front view of a state in which a plurality of vertical functional units are mounted side by side in a single unit storage frame, and a side sectional view showing the internal structure of the functional unit. 2 to 4 are diagrams showing the wiring structure of the main circuit with respect to the functional unit, FIG. 5 is an external view of the vertical functional unit, FIG. 6 is a state diagram in which the circuit breaker is OFF and the unit door is closed, and FIG. Fig. 8 is a state diagram when the circuit breaker is OFF and the unit door is opened. Fig. 8 is a state diagram when the unit door is closed and the circuit breaker is turned ON. FIG. 10 is an external view of the entire control center. In the illustrated control center, four functional units can be mounted side by side for each unit storage frame arranged in the upper and lower stages in the cabinet panel.

  First, in the external view of the control center shown in FIG. 10, the drawer-type functional unit 2 is mounted side by side inside a unit storage frame (not shown) arranged in a vertical row in the panel of the self-supporting cabinet 1. Yes. In addition, 3 is a front panel of a unit storage frame arranged on the front surface of the cabinet 1 with the front surface of each functional unit 2 facing forward, and 4 is a front panel of a cable processing chamber defined on the inner side of the cabinet 1. . Although not shown, a vertical bus (bar conductor) on the power supply side connected to the main circuit of the functional unit 2 at each stage is installed in the rear part of the cabinet 1 in the panel.

  Next, the assembly structure of the above-described drawer-type vertical functional unit 2 will be described with reference to FIGS. 1 (a), 1 (b) and FIG. That is, the functional unit 2 includes a circuit breaker (wiring circuit breaker) 22, a control transformer (current transformer) 23, an electromagnetic contactor 24, a controller 25, a control terminal block 26, and the like inside the unit frame 21. As shown in the figure, the devices are arranged one above the other, and a unit door 27 that opens and closes forward with the lower end as a hinge fulcrum is disposed on the front surface of the unit frame 21, and an automatically connected power supply side contact 28 on the rear surface side. (A grip-type contact plug corresponding to each phase of R, S, T) and a contact plug 29a of the load side contact 29 corresponding to each phase are provided and assembled. In addition, a notch window corresponding to the rotary operation handle 22a equipped in the circuit breaker 22 and the display unit 25a of the controller 25 is opened on the door plate surface of the unit door 27, and an interface described later is provided on the side surface of the door. An inverted L-shaped engagement groove 27a is formed in a notch for hooking on the lock plate of the lock mechanism and locking the unit door 27 in the closed position.

  On the other hand, the unit storage frame 5 which is installed in the upper and lower stages in the cabinet 1 shown in FIG. 10 and mounts the functional units 2 side by side is a box with an open front, and a drawer-type function is formed in the inside thereof. The unit 2 is individually inserted from the front and held in a predetermined storage position. Further, on the back side of the unit housing frame 5, the power source side vertical bus 6 (FIG. 2) is provided on the rear side of the cabinet 1 (see FIG. 10) with a power source side contact 28 provided on the back side of the functional unit 2. 4 contact sockets (receptacles) 29 b corresponding to the contact plugs 29 a of the load side contacts 29 are provided.

  Here, as shown in FIG. 3, the relay contact unit 7 includes a grip-type contact plug 7a corresponding to the R, S, and T phases of the vertical bus 6, and a horizontal bus 7b (bar conductor) connected to the contact plug 7a. The horizontal bus 7b is disposed in a recess formed on the back side of the unit storage frame 5 by being attached to an insulating support frame. As shown in FIG. 4, the back wall of the unit storage frame 5 has a square hole 5 a that opens to the horizontal bus 7 b corresponding to the power supply side contact 28 provided on the back of the functional unit 2. Yes.

  Further, a load connection terminal block 8 corresponding to four functional units 2 mounted in the frame is attached to the side wall of the unit storage frame 5, and at this position, the terminal block 8 and the contact socket 29b are connected to each other. There is a wiring connection between them. Reference numeral 9 denotes a load cable that leads to an external load.

  Further, in order to lock the drawer-type functional unit 2 housed in the unit housing frame 5 at the “connection position” and “disconnection position” in the panel, each functional unit is latched on the upper surface side of the unit frame 21. The mechanism 10 is equipped, and the release lever 10a of the latch mechanism protrudes forward from the upper side of the unit door 27. The latch mechanism 10 is for locking the functional unit 2 to the unit storage frame 5 at the “connection position” and “disconnection position” in the panel and locking the unit at this position. When the release lever 10a is pushed to the left side by operation, the lock is released and the function unit 2 can be pulled out and pushed.

  With the above configuration, when the functional unit 2 housed in the unit housing frame 5 is pushed into the “connection position” from the front, the power supply side contacts 28 provided on the back surface of the functional unit 5 are collectively connected to the horizontal bus 7 b of the relay contact unit 7. And is connected to the vertical bus 6 on the power supply side installed behind the inside of the panel via the contact plug 7a. At the same time, the plug 29a of the load side contact 29 of the functional unit 2 is automatically connected to the contact socket 29b arranged behind it, and is connected to the load cable 9 via the load connection terminal block 8 arranged on the side of the unit storage frame 5. Connected. As a result, automatic connection between the power supply side and the load side of the functional unit 2 is achieved. When the functional unit 2 is pulled out to the “disconnection position”, the main circuit on the power supply side and the load side are disconnected at the same time.

  Next, the structure, function, and operation of the interlock mechanism provided in the drawer type functional unit 2 will be described with reference to FIGS. In other words, the interlock mechanism of the illustrated embodiment is arranged above the circuit breaker 22 and has a first lock plate 11 whose one end (left end) is pivotally supported by the unit frame 21 and linked to the lock plate 11. It consists of a combination of a hinge-type second lock plate 12 provided on the right side surface of the unit frame 21 and a lock release rod 13 planted on the back surface of the unit door 27 so as to face the lock plate 12.

  Here, the first lock plate 11 is a rotating deformed cam plate having a lock cam portion 11b, a lock arm portion 11c, and a stopper portion 11d with a left end support shaft 11a as a fulcrum. The lock cam portion 11b is a circular shape. The cam surface has an arcuate cam surface, and the cam surface protrudes into the rotation path of the rotary interlock lever 22b of the circuit breaker connected to the operation handle 22a of the circuit breaker 22. The lock arm portion 11c extends toward an engagement groove 27a formed on the side surface of the unit door 27, and the stopper portion 11d faces the release lever 10a of the latch mechanism 10 described above from the upper edge of the cam plate. Standing up.

  Further, the second lock plate 12 is provided with a lock piece 12a protruding toward the upper side of the lock arm portion 11c on the movable piece of the hinge attached to the right side surface of the unit frame 21, and the lock piece 12a is always in the state of being locked. The hinge is spring-biased so as to protrude forward.

On the other hand, a release rod 13 protruding toward the movable piece of the second lock plate 12 is provided on the back surface of the unit door 27.
Next, the operation of the interlock mechanism configured as described above will be described. First, a state where the circuit breaker 22 is OFF and the unit door 27 is closed is shown in FIGS. In this state, the release rod 13 provided on the back surface of the unit door 5 pushes the hinge-type second lock plate 12 inward and rotates it counterclockwise, so that the lock piece 12a is attached to the first lock plate 11. It is retracted behind the lock arm 11c. Further, in a state where the operation handle 22 a of the circuit breaker 22 is stopped at the OFF position, the interlock lever 22 b moves backward to the left and is detached from the lock cam portion 11 b of the first cam plate 11. As a result, the first cam plate 11 rotates clockwise around the support shaft 11a, and the lock arm portion 11c is removed from the engagement groove 27a of the unit door 27 and retracted inward.

  Therefore, the unit door 27 can be opened without restriction in the circuit breaker OFF state. Further, after the unit door 27 is opened, the release lever 10a of the latch mechanism 10 is pushed to the release position, and the functional unit 2 can be pulled out from the “connection position” in the panel to the “disconnection position”.

  When the unit door 27 is pulled forward from the state shown in FIG. 6, the release rod 13 provided on the unit door 27 moves forward as shown in FIGS. The restraint of the plate 12 is released. As a result, the hinge-type second lock plate 12 receives the bias of the return spring and rotates in the clockwise direction, and the lock piece 12a protrudes above the lock arm portion 11c of the first lock plate 11, and the lock plate 11 is constrained to this position. Therefore, when the unit door 27 is opened, even if the operation handle 22a of the circuit breaker 22 is turned from the OFF position to the ON position, the interlock lever 22b is blocked by the lock cam portion 11b of the first cam plate 11 and the circuit breaker. 22 cannot be turned ON.

  On the other hand, when the operation door 22a of the circuit breaker 22 is turned to the ON position with the unit door 27 closed (see FIG. 6), as shown in FIGS. The lock lever 22b rotates clockwise to push up the lock cam portion 11b of the first lock plate 11 upward. As a result, the first cam plate 11 rotates upward with the support shaft 11a as a fulcrum, and the tip of the lock arm portion 11c protrudes into the engagement groove 27a of the unit door 27 in the closed state to lock the door in the closed position. To do. That is, the unit door 27 cannot be opened when the circuit breaker 22 is turned on. At the same time, the stopper portion 11d provided on the upper edge of the first cam plate 11 protrudes to the left side of the operation path with respect to the release lever 10a of the latch mechanism 10 and prevents the release operation of the latch mechanism 10. That is, in the ON state of the circuit breaker 22, the unit door 27 cannot be opened or the functional unit 2 cannot be moved in the panel.

  In addition, in the interlock state of FIG. 8, the release lever 10a of the latch mechanism 10 and the stopper portion 11d protruding on the operation path thereof are aligned on the same line with respect to the support shaft 11a of the first lock plate 11. . Therefore, even if a strong force is applied to the release lever 10a and pushed in, the cam plate does not rotate, thereby reliably preventing the latch mechanism 10 from being released.

  Next, a method for forcibly releasing the lock of the unit door 27 in order to perform an emergency inspection of the inside of the panel with the circuit breaker 22 in the ON state will be described with reference to FIGS. In other words, for the functional unit 2 to be forcibly released, the first lever 11 is locked by inserting a tool such as a screwdriver from the front into the gap between the unit door 27 and the adjacent functional unit. When the arm portion 11c is pushed up, as shown in FIG. 9C, the tip end of the lock arm portion moves to the upper end side of the engagement groove 27a. Thereby, the lock | rock of the unit door 27 is cancelled | released and a door can be opened.

  As can be seen from the above description of the operation, according to the interlock mechanism of the illustrated embodiment, the function is achieved by combining only three parts, the first lock plate 11, the second lock plate 12, and the release rod 13. The interlock function required for the unit 2 can be achieved.

BRIEF DESCRIPTION OF THE DRAWINGS It is a block diagram of this invention Example, (a) is a front view of the state which mounted the several vertical type functional unit side by side in the unit storage frame for one step, (b) represents the internal structure of a functional unit. Side view sectional view Fig. 1 is a bird's-eye view of the main circuit of the functional unit as seen from the front side when it is automatically connected to the power supply side and load side. An overhead view seen from the back side of FIG. The figure showing the state which pulled out the functional unit ahead in Drawing 2 External view of the functional unit in FIG. FIG. 6 is an explanatory diagram of an interlock mechanism equipped in the functional unit of FIG. 5, (a) is a perspective view of the inside of the unit with the circuit breaker turned off and the unit door closed, and (b) and (c) respectively. A top view and a front view schematically showing the mechanism of (a) FIG. 7 is an operation explanatory view of the interlock mechanism when the unit door is opened from the state of FIG. 6, (a) is a perspective view inside the unit, and (b) and (c) schematically show the mechanism of (a), respectively. Top view and front view FIG. 7 is an operation explanatory diagram of the interlock mechanism when the circuit breaker is turned on from the state of FIG. 6, (a) is a perspective view of the inside of the unit, and (b) and (c) are schematic views of the mechanism of (a). Front and side views It is operation | movement explanatory drawing of the interlock mechanism at the time of releasing the lock | rock of a unit door compulsorily in the state of the circuit breaker of FIG. 8, (a) is a perspective view inside a unit, (b), (c) is respectively A top view and a front view schematically showing the mechanism of (a) 1 is an external view of an entire control center according to an embodiment of the present invention.

DESCRIPTION OF SYMBOLS 1 Control center cabinet 2 Functional unit 21 Unit frame 22 Circuit breaker 22a Operation handle 22b Interlock lever 27 Unit door 28 Power supply side contact 29 Load side contact 29a Contact plug 29b Contact socket 5 Unit housing frame 6 Power supply side vertical bus 7 Relay contact unit 7a Contact plug 7b Horizontal bus 8 Load connection terminal block 10 Latch mechanism 10a Release lever 11 First lock plate (interlock mechanism)
11a Support shaft 11b Lock cam portion 11c Lock arm portion 11d Stopper portion 12 Second lock plate 13 Release rod

Claims (2)

Multiple drawer-type functional units consisting of a circuit breaker and assembly of monitoring and control devices are mounted side by side on the inside of the unit storage frame that is arranged in the upper and lower stages in a stand-alone cabinet. In the control center connected to the power supply side bus laid in the cabinet panel and the load connection terminal block,
For each of the functional units, automatic connection type power supply side and load side contacts are arranged on the back surface thereof, and the power supply side contacts are laid behind the inside of the panel on the back surface of the unit storage frame so as to face these contacts. A relay contact unit that connects to the vertical bus on the power supply side, and a contact socket that connects the load side contact to the load connection terminal block in the panel ,
In the unit storage frame, a square hole communicating with the relay contact unit corresponding to each of the power supply side contacts is opened, and the power supply side contact is automatically connected to the relay contact unit through the square hole,
A control center characterized in that a load connection terminal block corresponding to a functional unit mounted in the frame is provided on the side of the frame for each unit storage frame in the upper and lower stages. The control center according to claim 1, wherein a contact plug connecting the relay contact unit to each phase vertical bus on the power source side, and a horizontal bus laid along the back of the functional units arranged on the left and right side of the contact plug. A control center comprising an assembly of

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