JP2012110229A - Control center - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a control center which enables easy maintenance inspection of a smoothing capacitor of a power supply circuit part of a control unit 23.SOLUTION: An I/O circuit 2316, a control circuit 2317, a display circuit 2318, which are respectively formed on substrates, and a power supply circuit part 2315 are provided between a front surface panel 2313 and a rear surface panel 2314, which can be opened and closed, of a control unit 23. A bridge circuit 23151 of the power supply circuit part 2315 is formed on a power source circuit substrate 23154 in a power source cover 23153, and a smoothing capacitor 23152 of the power supply circuit part 2315 is mounted so as to be separated from the power source circuit substrate 23154 of the power source circuit part. This structure facilitates maintenance inspection of the smoothing capacitor of the power source circuit part.

Description

  The present invention converts an alternating current stepped down to a predetermined voltage into a direct current by a bridge circuit, a direct current obtained by smoothing a direct current output of the bridge circuit by a smoothing capacitor, an I / O circuit formed on a substrate, a control circuit, and The present invention relates to a control center in which a power supply circuit section for supplying power to the display circuit is built in a control unit.

A control unit constituting each of a plurality of rows constituting the control center is disclosed in, for example, Japanese Patent Laid-Open No. 6-153333 (Patent Document 1). In particular, the patent document 1 does not show the power supply circuit unit, but in actual products, the power supply circuit unit is often provided in the control unit.
In factories with relatively large scales, many conveyor motors, many pump motors, and many fan motors are installed, and the load status monitoring and control of these many motor loads is performed at a large control center consisting of many trains. Is called.

Japanese Patent Laid-Open No. 6-153333 (the figure and explanation in the summary)

  In a large control center composed of a large number of rows for monitoring and controlling the load states of a large number of motor loads, the number of control units constituting the rows is large, and therefore the number of power supply circuit sections is also large. By the way, a smoothing capacitor such as an electrolytic capacitor for smoothing the DC output of the bridge circuit is built in the power supply circuit section, and the smoothing capacitor such as the electrolytic capacitor is about 50% than other components although it depends on the operating environment temperature. Therefore, it is preferable that the smoothing capacitor can be maintained and inspected independently.

  The present invention has been made in view of the above circumstances, and converts an alternating current that has been stepped down to a predetermined voltage into a direct current with a bridge circuit, and a direct current obtained by smoothing the direct current output of the bridge circuit with a smoothing capacitor is obtained on a substrate. To facilitate maintenance and inspection of the smoothing capacitor in the power supply circuit section in the control center in which the power supply circuit section supplied as power to the I / O circuit, control circuit, and display circuit formed in the control unit is built in the control unit. It is intended.

The control center according to the present invention converts an alternating current stepped down to a predetermined voltage into a direct current with a bridge circuit, and a direct current obtained by smoothing a direct current output of the bridge circuit with a smoothing capacitor, an I / O circuit formed on a substrate, A control center in which a control circuit and a power supply circuit section for supplying power to the display circuit are built in the control unit,
The I / O circuit, the control circuit, the display circuit, and the power supply circuit unit are provided between an openable / closable front panel and a back panel of the control unit,
The smoothing capacitor of the power supply circuit unit is detachably attached to the power supply circuit board of the power supply circuit unit.

  According to the present invention, since the smoothing capacitor of the power supply circuit unit is detachably attached to the power supply circuit board of the power supply circuit unit, the smoothing capacitor of the power supply circuit unit can be easily inspected and maintained.

It is a figure which shows Embodiment 1 of this invention, and is a connection diagram which illustrates in figure an example of the concept of a control center. In the figure which shows Embodiment 1 of this invention, on the front panel of the control unit which comprises each of a plurality of rows, the load state monitoring screen which displays a load state, and the abnormality located in the vicinity of this load state monitoring screen It is a perspective view which illustrates schematically an example of the appearance of a control center provided with a display. BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows Embodiment 1 of this invention, and is a front view of the control unit illustrated in FIG. BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows Embodiment 1 of this invention, and is a top view of the control unit illustrated in FIG. FIG. 5 is a diagram illustrating the first embodiment of the present invention, and is an enlarged cross-sectional view illustrating an example of an internal configuration of an electronic device unit of a control unit when a cross section taken along a line VV in FIG. It is a figure which shows Embodiment 1 of this invention, and is an expanded sectional view which expands and shows further the part of the abnormality display apparatus in FIG. FIG. 7 is a diagram illustrating the first embodiment of the present invention, and is an external view of a portion of the abnormality display device in FIG. It is a figure which shows Embodiment 1 of this invention, and is the external view which looked at the light source of the abnormality display apparatus in FIG. 6 from the front side. It is a figure which shows Embodiment 1 of this invention, and is a perspective view of the lens of an abnormality display apparatus. It is a figure which shows Embodiment 1 of this invention, and is a connection diagram which shows an example of a power supply circuit. It is a figure which shows Embodiment 1 of this invention, and is a top view which shows an example of the external appearance of the power supply circuit part incorporated in the control unit. It is a figure which shows Embodiment 1 of this invention, and is the longitudinal cross-sectional rear view which looked at the cross section in the VIII-VIII line of FIG. 11 in the arrow direction. It is a figure which shows Embodiment 2 of this invention, and is the longitudinal cross-sectional rear view equivalent to FIG. 11 which looked at the cross section in the VIII-VIII line of FIG.

Embodiment 1 FIG.
Embodiment 1 of the present invention will be described below with reference to FIGS. In addition, in each figure, the same code | symbol shows the same part.

  First, FIG. 1 illustrating an example of the concept of the control center in a circuit, and a load state monitoring screen for displaying a load state on the front panel of the control unit constituting each of the plurality of rows, and the load state monitoring screen The concept of the control unit will be described with reference to FIG. 2 schematically illustrating an example of the appearance of a control center provided with an abnormality display device located in the vicinity of.

  As shown in FIG. 1 and FIG. 2, in a relatively large factory, a large number of motors 1 having a relatively large capacity such as a large number of conveyor motors, a large number of pump motors, a large number of fan motors, etc. The load state monitoring / control of the large number of motor loads is performed by a large control center 2 composed of a large number of rows.

  The control center 2 receives outputs of a load state detection sensor 21 such as a current transformer for detecting a motor load current, a contactor 22 such as an electromagnetic contactor that opens and closes a motor main circuit, and an output of the load state detection sensor 21. It is composed of a number of rows 24 including a control unit 23 that performs load state monitoring / control (including opening and closing of the motor main circuit by the contactor 22). FIG. 2 shows an example in which there are twelve rows 24 and six control units 23 in each row.

  Each control unit 23 includes an electronic device unit 231, and the electronic device unit 231 includes a load state monitoring screen 2311 for displaying a load state, an abnormality display device 2312, and the like. In other words, the control unit 23 includes a load state monitoring screen 2311, an abnormality display device 2312, and the like.

  FIG. 2 shows the signs of the electronic device unit 231, the load state monitoring screen 2311, and the abnormality display device 2312 of the uppermost control unit 23 of the farthest row board farthest from the passage AA in the storage building A of the control center 2. Although illustrated with lead lines, since the electronic device unit, the load state monitoring screen, and the abnormality display device can be discriminated from the drawing with respect to the control unit 23, their reference numerals are not shown. Similarly, since each control unit 23 can also be discriminated from the drawing, only the innermost board 24 farthest from the passage AA shows the sign of each control unit 23, and the others are not shown.

  As shown in FIG. 3 which is a front view of the electronic device unit 231 of the control unit 23 and FIG. 4 which is a plan view of the electronic device unit 231 of the control unit 23, an example of the electronic device unit 231 is shown. In addition to the abnormality display device 2312 located in the vicinity of the load state monitoring screen 2321, the front panel of FIG. 1 performs operations such as ON-OFF of the target motor 1 (see FIG. 1) (opening and closing of the contactor 32 (see FIG. 1)) An operation button 2313, a setting operator 2314 for setting an abnormal level of the load state, and the like are provided.

  The abnormality display device 2312 will be described in detail later. For example, a lens 23121 made of light-transmitting plastic for display at the front part thereof includes, for example, the lens 231211 for ON display, the lens 231212 for OFF display, and a load. It is composed of a lens 231213 for displaying an abnormal state and a lens 231214 for displaying an operation error in the control unit 23 (including in the electronic device unit 231). Further, in the illustrated example, these lenses 231211, 231212, 231213, and 231214 are arranged in a line at a predetermined interval in the vertical direction, all from the front surface of the electronic device unit 231 (that is, the front surface of the control unit 23). It protrudes forward by a predetermined length (see FIG. 4).

  The internal configuration of the electronic device unit 231 of the control unit 23 is, as illustrated in FIG. 4 which is an enlarged cross-sectional view taken along the line VV in FIG. Panel 2314, power circuit 2315, I / O circuit board 2316, control circuit board 2317, display circuit board 2318, connectors 2319, 2320, 2321, 2322, 2323, liquid crystal display panel 2324, liquid crystal display panel backlight 2325, transparent A window plate 2326 and a hinge 2327 are provided.

  The front panel 2313 constitutes the front panel of the control unit 23, and is formed of a light-impermeable resin or the like.

  The back panel 2314 is formed of resin or the like, and the load state detection sensor 21, the contactor 22 and the like built in the control unit 23 are disposed on the back side thereof.

  The power supply circuit unit 2315 is a power supply circuit that supplies DC power to the substrates 2316, 2317, and 2318. An example of the connection diagram is stepped down to a predetermined voltage by the step-down transformer 25 as illustrated in FIG. The built-in bridge circuit (AC / DC converter circuit) 23151 converts the alternating current into a direct current and then smoothes the direct current output of the bridge circuit 23151 with a built-in smoothing capacitor 23152 such as an electrolytic capacitor. The smoothed direct current is adjusted to a predetermined direct current output voltage by a positive power supply regulator 23157 and a negative power supply regulator 23158, and further stabilized by an output stabilization capacitor 23159. The power supply of the stabilized direct current output voltage is It is supplied to each substrate 2316, 2317, 2318. The detailed structure of the power supply circuit unit 2315 will be described later.

  The I / O circuit board 2316 is a board on which a so-called input / output circuit is formed, and a load state information signal (analog signal) detected by the load state detection sensor is input to the control circuit board 2317. The load state information signal is output.

  The control circuit board 2317 outputs display control signals necessary for the display devices 2311 and 2312 to the load status monitoring screen display device 2311 and the abnormality display device 2312 based on the input digital load status information signal. is there.

  The display circuit board 2318 receives the display control signal from the control circuit board 2317, and based on the display control signal, the display operation signal of the ON, the OFF, the abnormal load state, the operation error, It outputs to the abnormality display device 2312 and outputs a display operation signal such as a measured value of the load state to the load state monitoring screen display device 2311.

The connector 2319 connects the detection output signal line of the load state detection sensor 21 and the input terminal of the I / O circuit board 2316.
The connectors 2320 and 2321 connect the output terminal of the I / O circuit board 2316 and the input terminal of the control circuit board 2317, and connect the input / output terminals of both boards without using a harness. Therefore, it is also called a board-to-board connector.
The connector 2322 is a terminal that is provided in the power supply circuit unit 2315 and takes in an AC power supply (secondary output of a step-down transformer not shown).
The connector 2323 connects the output terminal of the control circuit board 2317 and the input terminal of the display circuit board 2318, and is the board-to-board connector.

  The liquid crystal display panel 2324 is a display panel using liquid crystal, and displays a measurement value of the load state and the like based on a display operation signal from the display circuit board 2318.

The backlight 2325 of the liquid crystal display panel is a light source that emits light toward the liquid crystal display panel 2324 from the back side of the liquid crystal display panel 2324, and makes the display of the liquid crystal display panel 2324 clear.
It should be noted that the light intensity of the backlight 2325 and / or the background color of the liquid crystal display panel 2324 is brighter in the event of an abnormality than in the steady state of the motor load based on the display operation signal from the display circuit board 2318. This makes it easier to visually recognize even a large number of rows.

  The transparent window plate 2326 protects the front surface of the liquid crystal display panel 2324 and is attached to the opening of the front panel 2313.

  The hinge 2327 is provided in the fixing portion 2328, and both the one end 2313A on the back surface side of the front panel 2313 and the one end 2314A on the same side as the one end 2313A of the front panel 2313 of the back panel 2314 are pivotally attached. By this pivot attachment, both the front panel 2313 and the back panel 2314 can be rotated individually in the direction of the arrow A about the hinge 2327 as an axis, that is, can be opened and closed with one opening.

  When the front panel 2313 is rotated (opened) about the hinge 2327 in the direction of arrow A, the front panel 2313, the display lens 23121, and the transparent window plate 2326 are centered on the hinge 2327. The power supply circuit unit 2315, the I / O circuit board 2316, the control circuit board 2317, and the display circuit which are rotated and opened integrally in the direction of the arrow A, and as a result are exposed to the outside. Maintenance inspection of the substrate 2318, the connectors 2319, 2320, 2321, 2322, 2323, the liquid crystal display panel 2324, the backlight 2325 of the liquid crystal display panel, and the like can be performed.

  Further, when the back panel 2314 is rotated (opened) in the direction of arrow A about the hinge 2327 as an axis, the back panel 2314, the power supply circuit unit 2315, the I / O circuit board 2316, and the control circuit board 2317. The display circuit board 2318, the connectors 2319, 2320, 2321, 2322, 2323, the liquid crystal display panel 2324, the backlight 2325 of the liquid crystal display panel, and the hinge 2327 are integrated in the direction of the arrow A. The load state detection sensor 21 and the contactor 22 that have been exposed to the outside as a result of being rotated and opened can be inspected for maintenance.

  Here, the structure of the abnormality display device 2312 will be described in detail with reference to FIGS. FIG. 6 is an enlarged cross-sectional view showing the portion of the abnormality display device 2312 in FIG. 5 further enlarged, FIG. 7 is an external view of the portion surrounding the light transmission portion of the lens 23121, and FIG. FIG. 9 is a perspective view of the lenses 23121, 231211, 231212, 231213, and 231214.

  The liquid crystal display is positioned at a predetermined distance from the liquid crystal display panel 2324, the backlight 2325 of the liquid crystal display panel, and the transparent window plate 2326 in the vicinity of the load state monitoring screen display device 2311 of the front panel 2313. A cylindrical portion 23131 that integrally protrudes from the front panel 2313 to the back side is formed in parallel with the stacking direction of the panel 2324, the backlight 2325 of the liquid crystal display panel, and the transparent window plate 2326.

The cylindrical portion 23131 has four (that is, a plurality of) lens mounting through holes 231111, 231312, 231313, and 231314 that penetrate from the rear surface side of the front panel 2313 to the front surface side and extend in parallel with each other. Is provided. Each of these lens mounting through holes 231111, 2331312, 231313, and 231314 has a rectangular shape such as a rectangle as shown in the drawing, and the sizes thereof are the same.
In other words, the cylindrical portion 23131 can be said to have a plurality of lens mounting through holes 231311, 2331312, 231313, and 231314 that pass through the front panel 2313 in the front-rear direction. The cylindrical portion having the mounting through hole 233131, the cylindrical portion having the lens mounting through hole 2331312, the cylindrical portion having the lens mounting through hole 231313, and the cylindrical portion having the lens mounting through hole 231314 are integrated. It can also be said that the formed cylindrical portion.

  The ON display lens 231211 is displayed in the lens mounting through-hole 2331311, the OFF display lens 231212 is displayed in the lens mounting through-hole 233131, and the abnormality in the load state is displayed in the lens mounting through-hole 231313. The lens 231213 for displaying the operation error is inserted into the lens mounting through-hole 231314, and is fixed in the corresponding lens mounting through-hole.

  Further, as shown in the drawing, the light receiving surfaces 23121S1 of the lenses 231211, 231212, 231213, and 231214 are positioned on the front side of the inner end surface 23131A of the cylindrical portion 23131, and the lenses 231211, 231212, 231213, and 231214 A recess 23131B is formed between each light receiving surface 23121S1 and the inner end surface 23131A of the cylindrical portion 23131.

The light source 23122 includes an ON display LED 231221 facing the ON display lens 231211, an OFF display LED 231222 facing the OFF display lens 231212, and a load condition abnormality display lens 231213. It is composed of an LED 231223 for displaying an abnormal load state and an LED 231224 for displaying an in-unit operation error facing a lens 231214 for displaying an in-unit operation error.

  In the illustrated example, the ON display LED 231221 is composed of three LEDs of green G, red R, and green G arranged at predetermined intervals, and the OFF display LED 231222 is arranged at predetermined intervals. It consists of three LEDs of green G, red R, and green G, and the LED 231223 for displaying the load condition abnormality is composed of two LEDs of orange O arranged at a predetermined interval, and the operation error display in the unit The red LED 231224 is composed of one red R LED.

  The red R ON-display LED 231221 when the switch is ON, the green G OFF-display LED 231222 when the switch is OFF, and the two orange O-load display LEDs 231223 when the load condition is abnormal However, when the in-unit operation error is detected, the red R LED 231224 for displaying the in-unit operation error emits light in response to a display drive signal from the display circuit board 2318.

  The LED 231221 for ON display has a light emitting surface 23122A at the front end located in the recess 23131B corresponding to the lens 231211 for opposing ON, and the LED 231222 for OFF display is opposed to the opposing OFF The front light emitting surface 23122A is located in the recess 23131B corresponding to the display lens 231212, and the load state abnormality display LED 231223 is opposed to the load state abnormality display lens 231213. The front light emitting surface 23122A is located in the corresponding recess 23131B, and the in-unit operation error display LED 231224 corresponds to the opposing in-unit operation error display lens 231214 corresponding to the recess 23131B. The front light emitting surface 23122A is located inside. That is, the light emitting surface 23122A on the front side of the light source 23122 is located in the light-impermeable cylindrical portion 23131, and the diffusion of light emitted from the light emitting surface 23122A is diffused by the cylindrical portion 23131. As a structure to be prevented.

  A gap g of a predetermined length is secured between the light emitting surface 23122A of the light source 23122 and the light receiving surface 23121S1 of the display lens 23121, and the light emitting surface 23122A of the light source 23122 and the display The lens 23121 has a structure that prevents the light receiving surface 23121S1 from coming into contact with the lens 23121.

  The display lens 23121, that is, the ON display lens 231211, the OFF display lens 231212, the load state abnormality display lens 231213, and the operation error display lens 231214 Also, a columnar light transmission unit 23121S2 that transmits the light incident from the light source 23122 to the light receiving surface 23121S1, and a light emission unit 23121S3 that protrudes outward from the front panel 2313 and emits the light transmitted by the light transmission unit 23121S2. have.

  As shown in FIG. 9, the light emitting portion 23121S3 includes a substantially flat first side surface 23121S31 having a substantially arched tip portion, and substantially parallel to the first side surface 23121S31 and a substantially arched tip portion. A substantially flat second side surface 23121S32, and a front surface 23121S33 extending substantially in an arch shape across the peripheral edge portion of the first side surface 23121S31 and the peripheral edge portion of the second side surface 23121S32, Each of the first side surface 23121S31, the second side surface 23121S32, and the front surface 23121S33 is provided with a texture 23121S34.

  As shown in FIG. 9, the light emitting portion 23121S3 includes a first flat side surface 23121S31 having a substantially arched tip portion, and substantially parallel to the first side surface 23121S31. A substantially flat second side surface 23121S32, and a front surface 23121S33 extending substantially in an arch shape across the peripheral edge portion of the first side surface 23121S31 and the peripheral edge portion of the second side surface 23121S32, If the first side surface 23121S31, the second side surface 23121S32, and the front surface 23121S33 are each provided with a texture 23121S34, the direction of the arrows a, b, c, d, e, that is, even when viewed from above. The light emitted from the light radiating unit 23121S3 is strong both when viewed from the bottom, the left and right, and when viewed from the front, and as a result of the trial test, for example, the light radiating unit 23121S3 is made hemispherical. Compared with the case where the entire surface is textured, the visibility is considerably improved. Therefore, in a large control center (see FIG. 2) composed of a large number of rows for monitoring and controlling the load states of a large number of motor loads, the control units 23, 23,. The anomaly display device 2312 can be viewed from a relatively distant position such as the factory passage AA without the observer approaching the line and checking it visually.

  An example of the arrangement of the power supply circuit section 2315 in the control unit 23 and the detailed structure of the power supply circuit section 2315 itself is the formation of the I / O circuit as shown in FIG. 5, FIG. 11 and FIG. The I / O circuit board 2316, the control circuit board 2317 on which the control circuit is formed, the display circuit board 2318 on which the display circuit is formed, and the power circuit part 2315 on which the power circuit is formed are controlled by the control circuit board 2317. The unit 23 is provided between the openable and closable front panel 2313 and the back panel 2314, and the power supply circuit section 2315 is disposed beside the I / O circuit board 2316 and adjacent to the board 2316. .

  The bridge circuit 23151 of the power supply circuit unit 2315 is formed on the power supply circuit board 23154 in the power supply cover 23153.

  The smoothing capacitor 23152 and the stabilization capacitor 23159 of the power supply circuit unit 2315 are attached to a capacitor attachment cover 23155 that is detachably attached to the power supply cover 23153.

  The capacitor attachment cover 23155 is disposed on the front panel 2313 side of the power supply cover 23153, and the capacitor attachment cover 23155 is provided at a corner of the power supply cover 23153 in order to ensure the strength of the power supply cover 23153. (See FIG. 11).

  The smoothing capacitor 23152 and the stabilizing capacitor 23159 are mounted on a capacitor mounting board 231552 mounted on the capacitor mounting cover 23155. The smoothing capacitor 23152 and the stabilization capacitor 23159 are disposed on the back panel 2314 side from the capacitor mounting board 231552.

  The capacitor attachment cover 23155 is detachably attached to the power supply cover 23153 by a slide type attachment / detachment structure.

  The capacitor mounting cover 23155 is removed from the power supply cover 23153 with the front panel 2313 opened as described above, with the capacitor mounting cover 23155 in the direction of the arrow as, that is, the I / O circuit board 2316. Slide in the direction away from.

  The capacitor mounting cover 23155 is attached to the power source cover 23153 with the front panel 2313 opened as described above, with the capacitor mounting cover 23155 in the direction opposite to the arrow as, that is, the I / O circuit. Slide in a direction approaching the substrate 2316.

A concave portion 231531 is formed on one of the capacitor mounting cover 23155 and the power supply cover 23153, and a convex portion 231551 engaged with the concave portion 231531 is formed on the other, and when the capacitor mounting cover is removed by the sliding method, the capacitor When the mounting cover 23155 is slid on the power supply cover 23153 in the direction of the arrow as, the convex portion 231551 rides on the shoulder 231532 outside the concave portion, so that the capacitor mounting cover 23155 is in the direction of the arrow al, that is, the Open to the front panel 2313 side. Further, by opening the capacitor attachment cover 23155 in the direction of the arrow al, it is possible to prevent the smoothing capacitor 23152 and the stabilization capacitor 23159 on the capacitor attachment cover 23155 from coming into contact with the power supply cover 23153.
In the illustrated example, the concave portion 231531 is provided on the power supply cover 23153 side, and the convex portion 231551 is provided on the capacitor mounting cover 23155 side. May be provided.

  The capacitor mounting board 231552 and the power supply circuit board 23154 are connected by a wire harness 23156, and by the connection at the wire harness 23156, the smoothing capacitor 23152 and the stabilizing capacitor 23159 on the capacitor mounting board 231552 The bridge circuit 23151 on the power circuit board 23154 is connected as shown in FIG.

Embodiment 2. FIG.
As illustrated in FIG. 13, the capacitor mounting board 231552 and the power supply circuit board 23154 are connected to each other by a female connector 231561 attached to the capacitor mounting board 231552 and the female connector 231561 attached to the power supply circuit board 23154. Are connected by a male connector 231562 that is detachably coupled to the smoothing capacitor 23152 and the stabilizing capacitor 23159 on the capacitor mounting board 231552, and the power supply circuit board 23154. The upper bridge circuit 23151 is connected as shown in FIG.

  Also in the second embodiment, a concave portion 231531 is formed on one side of the capacitor mounting cover 23155 and the power source cover 23153, and a convex portion 231551 engaging with the concave portion 231531 is formed on the other side, and the sliding of the capacitor mounting cover is performed. When the capacitor mounting cover 23155 is slid on the power source cover 23153 in the direction of the arrow as during removal in the system, the convex portion 231551 rides on the shoulder 231532 outside the concave portion, so that the capacitor mounting cover 23155 It opens in the direction of al, that is, toward the front panel 2313 side. Further, by opening the capacitor attachment cover 23155 in the direction of the arrow al, it is possible to prevent the smoothing capacitor 23152 and the stabilization capacitor 23159 on the capacitor attachment cover 23155 from coming into contact with the power supply cover 23153.

  The capacitor mounting board 231552, together with the capacitor mounting cover 23155, moves in the direction of the arrow as, al, the direction opposite to the arrow as, al during the removal and mounting of the capacitor mounting cover 23155, Although it is feared that an excessive force acts on the connectors 231561 and 231562, such a concern is eliminated by connecting with the wire harness 23156.

  As is clear from the above description and the respective drawings, the first embodiment has the following technical features.

Feature 1: A load state monitoring screen display device for displaying a load state and an abnormality display device located in the vicinity of the load state monitoring screen display device are provided on the front panel of the control unit constituting each of the plurality of rows. In the control center
The abnormality display device includes a light source disposed inside the front panel, a light receiving surface that passes through the front panel and receives light generated by the light source, and a columnar light transmission that transmits light incident on the light receiving surface. And a lens having a light emitting portion that projects outward from the front panel and emits light transmitted by the light transmitting portion,
The light emitting portion includes a substantially flat first side surface having a substantially arch-shaped tip portion, a substantially flat second side surface substantially parallel to the first side surface and a substantially arch-shaped tip portion, and the first side surface. A front surface extending substantially in an arch shape across the peripheral edge of one side and the peripheral edge of the second side;
A control center, wherein the first side surface, the second side surface, and the front surface are provided with a texture.

  Feature point 2: In the control center described in feature point 1, at least two pairs of the lens and the light source are provided, one pair displays an abnormal load state, and the other pair operates in the control unit. A control center that displays errors.

  Feature point 3: The control center according to feature point 2, wherein each pair of lenses is arranged side by side, and each pair of light sources is arranged side by side.

  Feature point 4: In the control center according to any one of feature points 1 to 3, the lens is mounted in a lens mounting through hole provided in the front panel, and the load state is provided in the control unit. A control center, wherein the light source is attached to a display control board that performs display control of a monitoring screen and light emission control of the light source.

  Feature point 5: In the control center according to any one of feature points 1 to 4, at least a portion of the front panel surrounding the light transmission part is formed of a light-impermeable resin, and the lens is a light-transmissive plastic. A control center, wherein the light source is an LED.

  Feature point 6: In the control center according to feature point 4 or feature point 5, the lens mounting through-hole is formed in a cylindrical portion integrally provided in the front panel, and the front surface is located in front of the inner end surface of the cylindrical portion. The control center, wherein the light receiving surface of the lens is located on the side, and a light emitting surface on the front side of the light source is located in the cylindrical portion.

  Feature point 7: The control center according to feature point 6, wherein a gap having a predetermined length is formed between the light receiving surface of the lens and the light emitting surface of the light source.

  Feature point 8: The control center according to any one of feature points 4 to 7, wherein the front panel is pivotable with respect to the display control board.

  Feature point 9: A control center characterized in that all the control units of each row board have at least one feature configuration of the feature points 1 to 8.

Feature 10: An alternating current stepped down to a predetermined voltage is converted into a direct current by a bridge circuit, and a direct current obtained by smoothing a direct current output of the bridge circuit by a smoothing capacitor is converted into an I / O circuit formed on a substrate, a control circuit, and A control center with a built-in power supply circuit section for supplying power to the display circuit in the control unit,
The I / O circuit, the control circuit, the display circuit, and the power supply circuit unit are provided between an openable / closable front panel and a back panel of the control unit,
The bridge circuit of the power circuit section is formed on a power circuit board in a power cover,
The control center, wherein the smoothing capacitor of the power supply circuit unit is attached to a capacitor attachment cover that is detachable from the power supply cover.

Feature point 11: In the control center described in feature point 10,
The control center, wherein the capacitor mounting cover is disposed on the front panel side of the power supply cover.

Feature point 12: In the control center described in feature point 10 or feature point 11,
The control center, wherein the capacitor mounting cover is disposed at a corner of the power supply cover.

Feature point 13: In the control center according to any one of feature point 10 to feature point 12,
A control center, wherein the smoothing capacitor is mounted on a capacitor mounting board mounted on the capacitor mounting cover.

Feature point 14: In the control center described in feature point 13,
The control center, wherein the smoothing capacitor is disposed closer to the back panel than the capacitor mounting substrate.

Feature point 15: In the control center according to any one of feature points 10 to 14,
The capacitor mounting cover is detachably attached to the power supply cover by a slide type attaching / detaching structure,
A concave portion is formed on one of the capacitor mounting cover and the power supply cover, and a convex portion engaging with the concave portion is formed on the other. When the capacitor mounting cover is removed by the sliding method, the convex portion is outside the concave portion. A control center characterized in that the capacitor mounting cover is opened by riding on the shoulder of the motor.

Feature point 16: In the control center according to any one of feature point 13 to feature point 15,
The control center, wherein the capacitor mounting board and the power circuit board are connected by a wire harness or a connector.

23 Control unit,
2313 Front panel,
2314 Back panel,
2315 Power supply circuit section,
23151 bridge circuit,
23152 smoothing capacitor,
23153 power cover,
23154 power circuit board,
2316 I / O circuit,
2317 control circuit,
2318 Display circuit.

Claims (4)

The alternating current that has been stepped down to a predetermined voltage is converted to direct current by a bridge circuit, and the direct current output of the bridge circuit is smoothed by a smoothing capacitor to the I / O circuit, control circuit, and display circuit formed on the substrate. A control center with a built-in power supply circuit section to supply power for the control unit,
The I / O circuit formed on the substrate, the control circuit, the display circuit, and the power supply circuit unit are provided between an openable front panel and a back panel of the control unit,
A control center, wherein the smoothing capacitor of the power supply circuit unit is detachably attached to a power supply circuit board of the power supply circuit unit. In the control center according to claim 1,
The bridge circuit of the power supply circuit section is formed on a power supply circuit board in a power supply cover, and the smoothing capacitor of the power supply circuit section is mounted on a capacitor mounting board separated from the power supply circuit board. center. In the control center according to claim 2,
A control center, wherein the capacitor mounting board and the power circuit board are connected by a connector. In the control center according to claim 2,
A control center, wherein the capacitor mounting board and the power circuit board are connected by a wire harness.

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