JP2014203108A - Control apparatus, program, and plate glass manufacturing apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To stably control an object to be controlled by an uninterruptible power supply having a relatively small capacity, and automatically restart drive of the object to be controlled even if voltage of an electric source for power is reduced.SOLUTION: A control apparatus (100) according to the present invention comprises: a drive section (110) which drives an object to be controlled (210) by electric power supplied from an electric source for power (D); a control section (120) which is connected to an uninterruptible power supply (220) and controls the drive section (110); and a voltage detector (130) which detects voltage from the electric source for power (D). The drive section (110) enters a stop state with reduction of voltage from the electric source for power (D), and the control section (120) outputs a cancel signal for cancelling the stop state of the drive section (110) to the drive section (110) on the basis of a detection result of the voltage detector (130).

Description

  The present invention relates to a control device, a program, and a sheet glass manufacturing apparatus.

  Control devices that control the driving of electric devices such as motors are currently used in many applications. For example, in a production line of a factory, it is considered to automate production by automating the control of electric devices.

  The control device controls the electric device with electric power supplied from a power source (for example, commercial power source). However, if an abnormality occurs in the power system due to a lightning strike, etc., and the power supply voltage drops or a power failure occurs, control of the control device stops, and the drive of the electric device can be resumed immediately. I can't. For example, in order to restart the driving of the electric device, the user needs to confirm whether or not the driving of the electric device can be restarted.

  For this reason, an apparatus using an uninterruptible power supply (UPS) has been proposed as an apparatus for compensating for power supply to an electric device (see, for example, Patent Document 1). Patent Document 1 describes an uninterruptible power supply that supplies power to a load device.

  Since the uninterruptible power supply described in Patent Document 1 backs up the power supplied to the load device, it continues to supply power to the load device even if the voltage of the power supply connected to the load device drops. Can be made. However, when the number and types of load devices are large, as described in Patent Document 1, if the uninterruptible power supply backs up the power supplied to all the load devices, the capacity of the uninterruptible power supply increases. . The larger the capacity of the uninterruptible power supply, the higher the price of the uninterruptible power supply and the larger the dimensions of the uninterruptible power supply, which increases the cost of the entire device equipped with the uninterruptible power supply and secures the installation location. Will become difficult.

  Therefore, in Patent Document 2, the uninterruptible power supply backs up the power supplied to the computer apparatus and the actuator control power supply, while the uninterruptible power supply does not back up the power supplied to the actuator power supply. A machine tool device is described. In the machine tool device of Patent Document 2, the uninterruptible power supply device does not back up the power supplied to the power source for driving the actuator, and suppresses the capacity of the uninterruptible power supply device. Further, in this machine tool device, when a power supply abnormality occurs for a short period, the actuators are retracted to suppress interference between the actuators.

JP 2002-218670 A JP-A-6-19520

  As described above, in the uninterruptible power supply of Patent Document 1, when the number and types of load devices are large, the capacity of the uninterruptible power supply may increase. In addition, as described above, the machine tool device of Patent Document 2 can suppress an increase in the capacity of the uninterruptible power supply, but may not be able to perform suitable control when the voltage of the power supply decreases. It was. For example, when a device such as a servo motor that automatically stops when the voltage of the power supply drops even for a short period of time is controlled as an object to be controlled, the operator may restore the servo motor before performing the save control. Necessary. However, the machine tool device of Patent Document 2 cannot easily resume the driving of the controlled object.

  The present invention has been made in view of the above problems, and its purpose is to stably control an object to be controlled using an uninterruptible power supply having a relatively small capacity, and due to a decrease in the voltage of the power supply. An object of the present invention is to provide a control device, a program, and a sheet glass manufacturing apparatus that can automatically resume the driving of the controlled object even when the driving of the controlled object stops.

  A control device according to the present invention includes a drive unit that drives a controlled object by electric power supplied from a power source, a control unit that is connected to an uninterruptible power supply and controls the drive unit, and a power source from the power source. A voltage detector for detecting a voltage, the drive unit is stopped in response to a decrease in the voltage of the power source for power, and the control unit is configured to drive the drive based on a detection result of the voltage detector. A release signal for releasing the stop state of the unit is output to the drive unit.

  In the control device according to the aspect of the invention, when the period in which the voltage detected by the voltage detector has decreased below the threshold voltage is equal to or greater than the threshold period, the control unit may When the control unit shifts to a standby state for waiting for resumption of control, and the control unit detects that the voltage detected by the voltage detector is lower than the threshold voltage is less than the threshold period, the control unit It is preferable to output a release signal.

  In the control device of the present invention, the control object is a servo motor, and the drive unit includes a servo amplifier that drives the servo motor, and the servo amplifier is supplied from the power source for power. The servo motor is driven by electric power, and when the voltage detected by the voltage detector drops below the threshold voltage, the servo amplifier stops driving the servo motor and enters an alarm state. The unit is configured to reset the alarm state of the servo amplifier as one of the release signals when a period during which the voltage detected by the voltage detector is reduced to be equal to or lower than the threshold voltage is less than the threshold period. The reset signal is preferably output to the servo amplifier.

  In the control device of the present invention, the drive unit further includes an electromagnetic contactor that switches on / off the power supply state from the power source to the servo amplifier according to a signal from the control unit, The control unit outputs a signal for turning off the power supply state to the electromagnetic contactor based on a detection result of the voltage detector, and then a signal for turning on the power supply state. It is preferable to output to the electromagnetic contactor.

  The program of the present invention provides a computer that controls the drive of a controlled object with the power supplied from the uninterruptible power supply, and the detection result of the voltage of the power source for supplying power to the drive unit that drives the controlled object. A receiving step and a step of outputting a release signal for releasing the stop state of the drive unit changed according to the voltage of the power source to the drive unit based on the detection result.

  A plate glass manufacturing apparatus according to the present invention includes a control object, the control device described above for controlling the control object, and a scribe head, and the plate glass and the scribe head are relatively moved by the control object. A scribe line is formed on the plate glass by moving the plate.

  The plate glass manufacturing apparatus of the present invention is provided with a first roller, a second roller, a glass holding member for holding the plate glass, and the glass holding member, and circulates around the first roller and the second roller to form the glass. It is preferable that the belt further moves a holding member, and the control object rotates at least one of the first roller and the second roller.

  The sheet glass manufacturing apparatus of the present invention further includes a disposal mechanism for discarding the sheet glass, and the control unit discards the sheet glass on which the scribe line is formed within a non-control period during which the drive unit is not controlled. It is preferable that an instruction signal is output to the discard mechanism, and the discard mechanism discards the plate glass based on the discard instruction signal.

  According to the control device of the present invention, the controlled object is stably controlled using the uninterruptible power supply device having a relatively small capacity, and the driving of the controlled object is stopped due to the voltage drop of the power source for power. Even in this case, the driving of the controlled object can be automatically restarted according to the voltage drop state.

It is a schematic diagram which shows embodiment of the control apparatus by this invention. It is a flowchart in the control apparatus of this embodiment. It is a schematic diagram which shows embodiment of the plate glass manufacturing apparatus by this invention.

  Hereinafter, embodiments of a control device, a program, and a sheet glass manufacturing device according to the present invention will be described with reference to the drawings. However, the present invention is not limited to the following embodiments.

  First, an embodiment of a control device 100 according to the present invention will be described with reference to FIG. The control device 100 controls the control object 210. The control device 100 controls the control object 210 using the control power source C and the power source D.

  The control object 210 is an electric device such as a motor or an electric actuator. For example, the control object 210 is a motor, and a specific example of the motor is a stepping motor or a servo motor. As the control object 210, an AC servo motor or a DC servo motor is preferably used.

  The control device 100 includes a drive unit 110, a control unit 120, and a voltage detector 130. The drive unit 110 drives the control object 210 with electric power supplied from the power source D for power. The drive unit 110 includes a drive circuit 112 and an electromagnetic contactor 114. The drive circuit 112 drives the control object 210. For example, when the control object 210 is a servo motor, the drive circuit 112 is a servo amplifier.

  The power source D for power is electrically connected to the controlled object 210 via the electromagnetic contactor 114 and the drive circuit 112. The electromagnetic contactor 114 is connected to the primary side of the drive circuit 112, and the electromagnetic contactor 114 switches the electrical connection between the power source D for driving and the drive circuit 112. The magnetic contactor 114 has an electromagnet. The electromagnetic contactor 114 switches the electrical connection between the power source D for driving and the drive circuit 112 in accordance with a signal output from the control unit 120 to the electromagnetic contactor 114. The electromagnetic contactor 114 can suppress burnout due to overload of the controlled object 210.

  The control unit 120 controls the drive unit 110. For example, the control unit 120 has a programmable logic controller (sequencer). The control unit 120 may include a dedicated machine having a central processing unit (CPU) or a general-purpose computer. Alternatively, the control unit 120 may include a motion controller in addition to the programmable logic controller. In addition, the control unit 120 preferably includes a storage unit such as a memory that stores a program for executing the processing of the flowchart described below with reference to FIG. The control unit 120 can perform automatic operation of the controlled object 210 by performing a sequence process. When the controlled object 210 is automatically operated, the electromagnetic contactor 114 electrically connects the power source D for driving and the drive circuit 112, and the drive circuit 112 drives the controlled object 210. Although not shown in FIG. 1, the control unit 120 may control members other than the drive unit 110 together with the drive unit 110.

  As described above, the control device 100 controls the control object 210 using the control power source C and the power source D. However, the voltages of the control power supply C and the power supply D may both decrease. For example, when an abnormality occurs in the power system due to lightning or the like, the voltage from the power supply may decrease for a short period. The phenomenon in which the voltage from the power source drops for a relatively short time is also called instantaneous voltage drop or instantaneous drop. Furthermore, not only the voltage of the power supply decreases, but also the power supply from the power supply is interrupted and a power failure may occur.

  The uninterruptible power supply 220 is electrically connected to the control power supply C and the control unit 120. The uninterruptible power supply 220 is also referred to as UPS (Uninterruptable Power Supply).

  The uninterruptible power supply 220 supplies power to the control unit 120 when the voltage of the control power supply C drops below a threshold voltage. Therefore, even if the voltage of the control power supply C decreases, the control unit 120 does not stop. Thus, the power supplied to the control unit 120 is backed up by the uninterruptible power supply 220.

  As described above, the uninterruptible power supply 220 is electrically connected to the control unit 120, but is not electrically connected to the drive unit 110. For this reason, the uninterruptible power supply 220 supplies power to the control unit 120, but does not supply power to the drive unit 110. As described above, the power supplied to the drive unit 110 is not backed up by the uninterruptible power supply 220, thereby reducing the capacity of the uninterruptible power supply 220.

  As described above, the drive unit 110 drives the control object 210. Since the uninterruptible power supply 220 does not back up the power supplied to the drive unit 110, when the voltage of the power supply D decreases, the drive of the controlled object 210 by the drive unit 110 stops.

  The voltage detector 130 is electrically connected to the power source D for power and the control unit 120. The voltage detector 130 detects the voltage of the power source D for power. For example, the voltage detector 130 monitors the energization state of each phase of the three-phase alternating current. The voltage detector 130 outputs a voltage detection signal indicating the detected voltage of the power source D to the control unit 120.

  When the voltage of the power supply D decreases, the control unit 120 shifts the drive unit 110 from the drive state to the stop state. For example, the control unit 120 stops the driving of the controlled object 210 by the driving circuit 112, or causes the electromagnetic contactor 114 to disconnect the electrical connection between the power source D for driving and the driving circuit 112, and as a result. The drive unit 110 shifts from the drive state to the stop state. Alternatively, the control unit 120 may stop the driving of the controlled object 210 by the driving circuit 112 and cause the electromagnetic contactor 114 to block the electrical connection between the power source D for driving and the driving circuit 112.

  When the voltage of the power source D for power is restored and the driving of the controlled object 210 is resumed, the control unit 120 determines whether or not the stop state of the driving unit 110 is released. When the stop state of the drive unit 110 is released, the control unit 120 resumes driving of the control target object 210. If necessary, after confirming that the stop state of the drive unit 110 has been released, the control unit 120 determines whether or not other members are in an operable state. The driving of the object 210 is resumed.

  In the control device 100 of this embodiment, the control unit 120 outputs a release signal for releasing the stop state of the drive unit 110 to the drive unit 110 based on the detection result of the voltage detector 130. For example, when the voltage of the power source D for power decreases for a relatively long period, the control unit 120 shifts from the operation state to the standby state and continues the stop state of the drive unit 110 without outputting a release signal to the drive unit 110. Let In this case, the standby state of the control unit 120 continues until a recovery signal is received from the outside. When resuming driving of the control object 210, when the user outputs a recovery signal from the outside to the control unit 120, the control unit 120 releases the stopped state of the drive unit 110, and then other members can be operated. Check if it is in a state. When the vehicle is in the operable state, the driving of the control object 210 is resumed. As described above, the control unit 120 resumes driving of the controlled object 210 based on a user instruction.

  On the other hand, when the voltage of the power source D for power decreases for a relatively short period, the control unit 120 outputs a release signal for releasing the stop state of the drive unit 110 to the drive unit 110. For example, the control unit 120 outputs a reset processing signal to the drive circuit 112 to make the drive circuit 112 ready for operation.

  Further, for example, when the drive circuit 112 is a servo amplifier, the electromagnetic contactor 114 remains electrically connected to the power supply D and the drive circuit 112 even when the voltage of the power supply D decreases. Therefore, when the voltage of the power source D for power decreases for a relatively short period, the control unit 120 outputs a signal to the electromagnetic contactor 114 that temporarily disconnects the electrical connection between the power source D for power and the drive circuit 112, Thereafter, the control unit 120 outputs a signal for electrically connecting the power source D for driving and the drive circuit 112 to the electromagnetic contactor 114 again. In this way, the servo amplifier is reset.

  After the control unit 120 cancels the stop state of the drive unit 110, the control unit 120 may determine whether or not the operation is possible. When in the operable state, the control unit 120 resumes driving of the control object 210 by the drive circuit 112. Therefore, according to the control device 100 of the present embodiment, when the voltage of the power source D is decreased, the driving unit 110 is not always kept stopped, but the voltage decrease period in which the voltage of the power source D is decreased. Accordingly, the driving of the controlled object 210 can be automatically restarted.

  For example, the voltage drop period is a period from when the voltage of the power source D for power is lowered to about 90% or less of the rated voltage to when it recovers to a value exceeding about 90% of the rated voltage. For example, the control unit 120 outputs a release signal to the drive unit 110 when the voltage drop period is shorter than the threshold period, and does not output a release signal to the drive unit 110 when the voltage drop period is equal to or greater than the threshold period.

  For example, the threshold period is about 2 seconds. When the voltage drop period is less than 2 seconds, the control unit 120 outputs a release signal to the drive unit 110. The threshold period is determined based on the safety of the user who uses the control device 100.

  For example, when the control object 210 is a motor, as described above, if the period during which the voltage of the power source D is decreasing is relatively short, the control unit 120 continues to control the motor. However, the motor may free run after the voltage of the power source D for power drops. In this case, the control unit 120 controls the motor after rotating it to the rotational position after the completion of the control operation when the voltage drops or the rotational position before starting the control operation when the voltage drops. It is preferable to resume.

  The drive circuit 112 may monitor the state of the power source D for power. When the drive circuit 112 detects a decrease in the voltage of the power supply D, the drive circuit 112 may stop driving the control object 210. For example, when a servo motor is used as the control object 210 and a servo amplifier is used as the drive circuit 112, the servo amplifier monitors the energization state of the power source D for power. When the voltage of the power supply D decreases, the servo amplifier enters an alarm state, stops driving the servo motor, and outputs an alarm signal to the control unit 120.

  In addition, different power sources may be input to the drive circuit 112 as a main power source and a control power source. For example, the drive circuit 112 monitors at least one of the main power supply and the control power supply. When the drive circuit 112 detects a decrease in the voltage of either the main power supply or the control power supply, the drive circuit 112 outputs an alarm signal to the control unit 120. The driving of the control object 210 may be stopped.

  Below, the flowchart in the control apparatus 100 of this embodiment is demonstrated with reference to FIG. 1 and FIG.

  First, as shown in S202, the control unit 120 starts automatic operation. Typically, the user operates an input device (not shown) connected to the control unit 120 to give an instruction to start automatic operation, and the control unit 120 that receives a signal from the input device performs automatic operation. Start. Next, as shown in S204, the control unit 120 performs automatic operation. For example, the control unit 120 causes the drive unit 110 to drive the control object 210.

  While the automatic operation is performed, the voltage detector 130 detects the voltage of the power source D for power. As shown in S206, the control unit 120 determines whether or not the voltage of the power source D for power has dropped based on the detection result of the voltage detector 130. For example, the voltage detector 130 monitors the voltage state of the power source D for power, and the voltage detector 130 outputs a voltage detection signal indicating the voltage state of the power source D for power to the control unit 120. Based on the voltage detection signal, control unit 120 determines whether or not the voltage of power source D for power has dropped.

  The determination as to whether or not the voltage of the power source D for driving has dropped may be made based on the signal from the drive circuit 112 as well as the signal from the voltage detector 130. As described above, when the drive circuit 112 is a servo amplifier, the servo amplifier outputs an alarm signal to the control unit 120 when the voltage of the power supply D decreases. In this case, the control unit 120 not only indicates that the voltage detection signal from the voltage detector 130 indicates a decrease in the voltage of the power source D but also receives an alarm signal from the servo amplifier. You may determine with the voltage falling. As a result, it is possible to prevent the control unit 120 from malfunctioning based on one malfunction of the servo amplifier and the voltage detector 130.

  As a result of the determination, when the voltage of power source D for power is not lowered (NO in S206), control unit 120 continues the automatic operation as shown in S204. Thereafter, when a predetermined period has elapsed, the control unit 120 determines again whether or not the voltage of the power source D for power has dropped based on the detection result of the voltage detector 130 as shown in S206. The continuation of the automatic operation and the determination as to whether or not the voltage of the power source D has decreased are repeated until a decrease in the voltage of the power source D is detected.

  When the voltage of power source D for power decreases (YES in S206), control unit 120 stops the automatic operation of controlled object 210 as shown in S208. Specifically, the control unit 120 outputs a stop instruction signal for stopping the driving of the control target object 210 to the drive circuit 112. Alternatively, the control unit 120 causes the magnetic contactor 114 to disconnect the electrical connection between the power source D for driving and the drive circuit 112. Alternatively, the control unit 120 may cause the drive circuit 112 to stop driving the controlled object 210 and cause the electromagnetic contactor 114 to block electrical connection between the power source D for driving and the drive circuit 112.

  The control unit 120 stops the automatic operation of the controlled object 210 by putting the drive unit 110 in a stopped state. After the drive unit 110 is stopped, the control unit 120 starts counting the voltage drop period as shown in S210.

  After that, when the voltage of the power source D is restored, the control unit 120 determines whether or not the voltage drop period is less than the threshold period. In the control device 100 of the present embodiment, the control unit 120 determines whether or not the voltage drop period is less than 2 seconds, as shown in S212.

  As a result of the determination, when the voltage drop period is not less than 2 seconds (that is, when the voltage drop period is 2 seconds or more) (NO in S212), the control unit 120 enters a standby state, and the drive unit as shown in S218. 110 is stopped. For example, the control device 100 may be connected to a display device such as a lamp or a monitor, and in S218, the control unit 120 may cause the display device to display that it is in a standby state. After that, when the driving of the control object 210 is resumed, the user confirms whether or not the other member is in an operable state, and then operates the input device (not shown) to drive the driving unit 110. The stop state is released, and thereafter, the control unit 120 is instructed to resume automatic driving. Based on the user's instruction, the control unit 120 resumes driving of the controlled object 210.

  If the voltage drop period is less than 2 seconds (YES in S212), control unit 120 outputs a release signal for releasing the stopped state of drive unit 110 to drive unit 110 as shown in S214. The stop state of the drive unit 110 is released based on the release signal.

  After outputting the release signal, the control unit 120 determines whether or not the vehicle is ready for operation as shown in S216. For example, the control unit 120 determines whether another member different from the drive unit 110 is in a drivable state. If the result of determination is that the vehicle is ready for operation (YES in S216), control unit 120 resumes automatic operation as shown in S204.

  As a result of determining whether or not the operation is possible, if the operation is not possible (NO in S216), the control unit 120 continues the stop state of the drive unit 110 as shown in S218. In addition, after that, when the operation is enabled and the driving of the control object 210 is resumed, the user confirms whether other members are in an operable state after canceling the stop state of the drive unit 110, Thereafter, based on the user's instruction, the control unit 120 resumes driving of the controlled object 210.

  In addition, for example, when the voltage of the power source D is lowered and the movement of the member is interrupted while the control object 210 is being driven so as to move the certain member, the control unit 120 is interrupted in S214 of FIG. The member may be moved so that the moving operation interrupted by the voltage drop is completed after the release signal is output in step S <b> 216 and before determining whether or not the operation is possible in step S <b> 216. In this case, the tact time of the moving operation can be shortened. For example, when the control object 210 is a servo motor, the controller 120 resumes driving of the servo motor after positioning the servo motor at the target position immediately before the voltage of the power supply D is stopped.

  Note that it is not always necessary to move the member so that the moving operation interrupted by the voltage drop is completed before determining whether or not the operation is possible. For example, the member may be moved to a position before starting the moving operation interrupted by the voltage drop before determining whether the operation is possible, thereby causing the moving operation to be accurately executed. Can do. Alternatively, the member may be moved in accordance with the position during the moving operation interrupted by the voltage drop before determining whether or not the operation is possible. It is possible to move the member in consideration of both of the accuracy.

  In FIG. 1, the control device 100 is shown such that the control unit 120 controls only the drive unit 110, but the present invention is not limited to this. The control unit 120 may control another member in addition to the drive unit 110.

  In the description with reference to FIG. 1, the drive unit 110 includes the drive circuit 112 and the electromagnetic contactor 114, but the present invention is not limited to this. The drive unit 110 may not have the electromagnetic contactor 114 as necessary. In this case, the control unit 120 may output a reset processing signal to the drive circuit 112 as a release signal.

  Although not particularly illustrated in FIG. 1, the control device 100 may further include a circuit breaker. The breaker breaks the electrical connection when an overcurrent or a short-circuit current flows through the wiring that electrically connects the power source D for power and the control object 210. The breaker is preferably disposed on the primary side of the magnetic contactor 114.

  The control apparatus 100 of this embodiment is used suitably for manufacturing equipment. For example, as will be described later with reference to FIG. 3, the control device 100 is suitably used as a part of a plate glass manufacturing apparatus that processes or cuts a plate glass. For example, when the control target 210 is a servo motor, the servo motor transmits power by rotating, for example, a ball screw, a belt, or a trochoid cam gear (TCG) runner.

  Hereinafter, with reference to FIGS. 1-3, embodiment of the plate glass manufacturing apparatus 300 by this invention is described. The plate glass manufacturing apparatus 300 of the present embodiment transports the plate glass G and forms scribe lines on the plate glass G.

  The plate glass manufacturing apparatus 300 includes a control device 100, control objects 210a and 210b, an uninterruptible power supply 220, a transport unit 310, and a scribe forming unit 320. The control device 100 in the plate glass manufacturing apparatus 300 of the present embodiment is the same as the control device 100 described above with reference to FIG. 1 except that it includes drive units 110a and 110b that drive the control objects 210a and 210b. In order to avoid redundancy, duplicate descriptions are omitted. The driving units 110a and 110b are electrically connected to a common power source D, and the voltage detector 130 is a power source in the wiring that electrically connects the power source D and the driving unit 110a. The voltage of D is detected.

  The control device 100 controls the control objects 210a and 210b. For example, the control objects 210a and 210b are servo motors, and the drive circuits 112a and 112b are servo amplifiers. For example, the rated output voltage of the control power supply C is 100V, and the rated output voltage of the power supply D is 200V.

  The conveyance part 310 conveys the plate glass G in the state which hold | maintained the plate glass G in parallel with the perpendicular direction. The conveyance unit 310 includes rollers 312a and 312b, a belt 314, and a holding member 316. The rollers 312a and 312b are configured to be rotatable, and the roller 312a rotates as the controlled object 210a rotates.

  The belt 314 is rotatably stretched by rollers 312a and 312b. The rollers 312a and 312b and the belt 314 are configured so that the belt 314 can go around the rollers 312a and 312b by the rotation of the rollers 312a and 312b.

  The holding member 316 is attached to the belt 314, and the holding member 316 holds the plate glass G. The holding member 316 moves along with the belt 314 along the horizontal direction. For example, as the holding member 316, a suction pad that adsorbs one main surface of the plate glass G with negative pressure, or an elastic pad that holds the plate glass G from both main surfaces of the plate glass G can be used.

  When the roller 312a rotates with the rotation of the control object (servo motor) 210a, the belt 314 starts moving and the roller 312b also starts rotating. Thus, since the belt 314 rotates by the rotation of the control object (servo motor) 210a, the holding member 316 attached to the belt 314 moves, and as a result, the plate glass G is conveyed.

  The scribe forming unit 320 forms a scribe line on the plate glass G. The scribe forming unit 320 includes rollers 322a and 322b, a belt 324, and a scribe head 326. The rollers 322a and 322b are configured to be rotatable, and the roller 322a rotates with the rotation of the control object 210b.

  The belt 324 is rotatably stretched by rollers 322a and 322b. The rollers 322a and 322b and the belt 324 are configured so that the belt 324 can go around the rollers 322a and 322b by the rotation of the rollers 322a and 322b.

  The scribe head 326 is attached to the belt 324, and the scribe head 326 moves along with the belt 324 along the vertical direction. For example, a wheel cutter is provided at the tip of the scribe head 326.

  When the roller 322a rotates with the rotation of the control object (servo motor) 210b, the belt 324 starts to move, and the roller 322b also starts to rotate. In this way, the belt 324 rotates by the rotation of the control object (servo motor) 210b. Accordingly, when the controlled object (servo motor) 210b rotates with the tip of the scribe head 326 in contact with the plate glass G, the scribe head 326 attached to the belt 324 moves, and as a result, the scribe head 326 is moved to the plate glass. A scribe line is formed on G. In addition, the plate glass G in which the scribe line was formed is conveyed to a cleaving apparatus and cleaved. The control unit repeatedly executes such control of the controlled object during automatic operation.

  As described above, in the plate glass manufacturing apparatus 300 of this embodiment, the controlled object 210b moves the scribe head 326 by rotating the roller 322a and rotating the belt 324. However, the control object 210b may move the scribe head 326 by rotating a ball screw to which the scribe head 326 is attached.

  Further, as described above, the plate glass manufacturing apparatus 300 of the present embodiment forms the scribe lines on the plate glass G by relatively moving the plate glass G and the scribe head 326 by the control target object 210a and the control target object 210b. When the voltage of the power source D for power has decreased for a relatively long period of time, the control unit 120 does not output the release signal to the drive units 110a and 110b, and continues the stopped state of the drive units 110a and 110b. In addition, when restarting the drive of the control target objects 210a and 210b, the user confirms whether or not other members are in a drivable state after canceling the stopped state of the drive units 110a and 110b. For example, the user checks whether or not a cleaving mechanism (not shown) that cleaves the glass sheet G on which the scribe line is formed is operable by the scribe forming unit 320. Thereafter, the control unit 120 resumes driving of the controlled objects 210a and 210b based on the user's instruction.

  Further, when the voltage of the power source D for power recovery is recovered in a relatively short period, the control unit 120 outputs a release signal for releasing the stop state of the drive units 110a and 110b to the drive units 110a and 110b. For example, the control unit 120 outputs a reset processing signal to the drive circuits 112a and 112b, and makes the drive circuits 112a and 112b operable. Alternatively, the control unit 120 outputs a signal for electrically connecting the power source D for driving and the drive circuits 112a, 112b to the electromagnetic contactors 114a, 114b, and the power source D for driving and the drive circuits 112a, 112b. Are electrically connected.

  In addition, while the scribe forming unit 320 is forming the scribe line on the plate glass G, or immediately before the scribe forming unit 320 forms the scribe line on the plate glass G, the voltage of the power source D decreases, and the control unit When the controlled objects 210a and 210b are driven in a state where the drive unit 110a and 110b are not controlled by the 120, the scribe forming unit 320 may form an unintended scribe line on the plate glass G. For this reason, when the voltage of the power source D for power supply decreases, the control unit 120 is scribed by the scribe forming unit 320 during the non-control period in which the drive units 110a and 110b are not controlled, regardless of the length of the voltage decrease period. You may control so that the sheet glass G in which the line | wire was formed is made to discard to a disposal mechanism (not shown). In this case, the transport unit 310 may be used as at least a part of the disposal mechanism. As described above, the control unit 120 outputs a discard instruction signal for discarding the glass sheet G on which the scribe line is formed within the non-control period during which the drive units 110a and 110b are not controlled, to the discard mechanism. It is preferable to discard the plate glass G based on the instruction signal.

  In addition, when the control unit 120 is controlling the control objects 210a and 210b and the voltage of the power source D decreases and the control of the control objects 210a and 210b is interrupted, in S214 of FIG. After outputting the release signal and before determining whether or not the vehicle is ready for operation in S216, the suspended control of the control objects 210a and 210b is resumed, and is suspended due to a decrease in the voltage of the power source D for power. Control may be completed. Or you may control to return to the state before performing control of the control target object 210a, 210b interrupted by the fall of a voltage. Further, the interrupted control operation of the control objects 210a and 210b may be completed or temporarily returned to the state before the interruption according to the position where the voltage drop of the power source D has occurred. Good.

  For example, when the control unit 120 is driving the control object (servo motor) 210a to transport the glass sheet G, the voltage of the power source D decreases and the transport of the glass sheet G is interrupted. The glass sheet G may be positioned after the release signal is output in step S214 and before determining whether or not the operation is possible in step S216. When the control objects 210a and 210b are servo motors and the drive circuits 112a and 112b are servo amplifiers, the servo amplifier detects the current rotational position of the servo motor, and the control unit 120 adds the servo motor to the servo amplifier. It can be rotated to a predetermined rotational position.

  When positioning the plate glass G, for example, the conveyance of the plate glass G may be resumed, and the conveyance operation of the plate glass G interrupted by the decrease in the voltage of the power source D may be completed. Alternatively, the plate glass G may be conveyed so as to return to the position before the movement interrupted by the decrease in the voltage of the power source D for power. Furthermore, the conveyance position of the plate glass G may be determined according to the distance from the position where the voltage drop has occurred.

  In the above description with reference to FIG. 3, the control object 210 a rotates the roller 312 a of the transport unit 310, but the present invention is not limited to this. The control object 210a may rotate the roller 312b of the transport unit 310, or the control object 210a may rotate both the rollers 312a and 312b. Similarly, in the above description with reference to FIG. 3, the control object 210b rotates the roller 322a of the scribe forming unit 320, but the present invention is not limited to this. The control object 210b may rotate the roller 322b of the scribe forming unit 320, or the control object 210b may rotate both the rollers 322a and 322b.

  In the above description with reference to FIG. 3, the control objects (servo motors) 210a and 210b are used to move the holding member 316 and the scribe head 326, but the present invention is not limited to this. The control object may be used for another application, and the control unit 120 may control other parts of the plate glass manufacturing apparatus 300 in synchronization with the control of the control objects 210a and 210b. For example, the control unit 120 may control a cleaving mechanism for the glass sheet G.

  Note that when determining whether or not the members other than the drive unit 110 and the control target 210 are in an operable state, the control unit 120, for example, should be moved by a cylinder or the like, but moves differently from the command. Determine whether or not. Alternatively, the control unit 120 may determine whether or not the plate glass G is broken. When it is not in the operable state, the control unit 120 continues the stopped state of the drive units 110a and 110b. As described above, the control device 100 of this embodiment is suitably used as a part of the plate glass manufacturing apparatus 300.

  According to the control device of the present invention, the control object can be stably controlled using the uninterruptible power supply device having a relatively small capacity, and the drive of the control object is automatically performed even when the drive of the control object is stopped. Can be resumed automatically. Such a control apparatus is used suitably for manufacture of plate glass.

DESCRIPTION OF SYMBOLS 100 Control apparatus 110 Drive part 112 Drive circuit 114 Electromagnetic contactor 120 Control part 130 Voltage detector 210 Control object 220 Uninterruptible power supply 300 Sheet glass manufacturing apparatus

Claims (8)

A drive unit that drives the object to be controlled by electric power supplied from a power source for power;
A control unit connected to the uninterruptible power supply and controlling the drive unit;
A voltage detector for detecting a voltage from the power source for power,
The drive unit is stopped in response to a decrease in the voltage of the power source for power,
The said control part is a control apparatus which outputs the cancellation | release signal for releasing the said stop state of the said drive part to the said drive part based on the detection result of the said voltage detector. The control unit waits to resume control of the drive unit until receiving a recovery signal from the outside when a period during which the voltage detected by the voltage detector has decreased to a threshold voltage or less is a threshold period or more. Transition to the state,
2. The control unit according to claim 1, wherein the control unit outputs the release signal to the driving unit when a period in which the voltage detected by the voltage detector is reduced to be equal to or lower than the threshold voltage is less than the threshold period. Control device. The controlled object is a servo motor,
The drive unit has a servo amplifier that drives the servo motor,
The servo amplifier drives the servo motor with the power supplied from the power source for power,
When the voltage detected by the voltage detector drops below the threshold voltage, the servo amplifier stops driving the servo motor and enters an alarm state.
The control unit resets the alarm state of the servo amplifier as one of the release signals when a period during which the voltage detected by the voltage detector has dropped below the threshold voltage is less than the threshold period. The control device according to claim 2, wherein a reset signal is output to the servo amplifier. The drive unit further includes an electromagnetic contactor that switches on / off a power supply state from the power source to the servo amplifier in response to a signal from the control unit,
The control unit outputs a signal for turning off the power supply state to the electromagnetic contactor based on a detection result of the voltage detector, and then a signal for turning on the power supply state. The control device according to claim 3, wherein the control device outputs the electromagnetic contactor. To the computer that controls the drive of the controlled object by the electric power supplied from the uninterruptible power supply,
Receiving a detection result of a voltage of a power source for power that supplies power to a drive unit that drives the control object; and
A program for executing a step of outputting, to the drive unit, a release signal for releasing the stop state of the drive unit that has been changed according to the voltage of the power source based on the detection result. Control object,
The control device according to any one of claims 1 to 4, which controls the control object;
With a scribe head,
A plate glass manufacturing apparatus that forms a scribe line on the plate glass by relatively moving the plate glass and the scribe head by the control object. A first roller;
A second roller;
A glass holding member for holding the plate glass;
A belt that is provided with the glass holding member and moves around the first roller and the second roller to move the glass holding member;
The plate glass manufacturing apparatus according to claim 6, wherein the control object rotates at least one of the first roller and the second roller. A disposal mechanism for discarding the plate glass;
The control unit outputs a discard instruction signal for discarding the plate glass on which the scribe line is formed within a non-control period during which the drive unit is not controlled to the discard mechanism,
The plate glass manufacturing apparatus according to claim 6 or 7, wherein the discard mechanism discards the plate glass based on the discard instruction signal.

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