JP2014199521A - Power monitoring device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a power monitoring device capable of recording power data of a monitoring target device under a predetermined condition.SOLUTION: A power monitoring device according to an embodiment includes: a data input unit that receives either a power value which is consumed by a monitoring target device or a voltage value and current value which are supplied to the monitoring target device; a memory that stores a program for starting or stopping either the recording of the power value or the recording of the power value which is calculated on the basis of the voltage value and current value; and an arithmetic processing unit that starts or stops the recording of the power value according to the program.

Description

  Embodiments according to the present invention relate to a power monitoring apparatus.

  In recent years, there are many demands for monitoring the power consumption of devices such as machine tools (hereinafter also referred to as monitored devices) for energy saving or the like. However, many monitored devices do not have a power monitoring function. Therefore, in order to monitor the power consumption of an existing monitored device, it is necessary to separately attach a power monitoring device to the monitored device.

Japanese Patent No. 2545465 JP-A-9-233734 JP 2012-181656 A JP 2010-130873 A

  However, although the conventional power monitoring apparatus can monitor the power consumption of the monitored apparatus, it cannot set detailed monitoring conditions. Therefore, unless the operator operates, the power monitoring device cannot start monitoring the power consumption of the monitored device or cannot stop monitoring the power consumption of the monitored device. In addition, during power consumption monitoring, the power monitoring apparatus continuously monitors power consumption. For this reason, the power monitoring apparatus needs a large-capacity memory to store data. If the storage capacity of the memory is not sufficient, the power monitoring apparatus may not be able to record necessary power data.

  Even if all the power data can be stored in the memory, it is necessary to extract power data necessary for analysis from a large amount of power data when analyzing the power consumption of the monitored apparatus. For this reason, it took a long time to analyze the power consumption of the monitored apparatus.

  On the other hand, it is difficult to provide an installed monitored apparatus with a power monitoring function without an external power monitoring apparatus, and the cost increases.

  Therefore, the present invention has been made to solve the above-described problems, and it is an object of the present invention to provide a power monitoring apparatus that can record power data of a monitored apparatus under a preset condition.

  The power monitoring apparatus according to the present embodiment includes a data input unit that receives a power value consumed in the monitored apparatus, or a voltage value and a current value supplied to the monitored apparatus, a recording of the power value, or a voltage value. And a memory for storing a program for starting or stopping recording of the power value calculated based on the current value, and an arithmetic processing unit for starting or stopping recording of the power value according to the program.

  The program includes a start condition and a stop condition for recording the power value, and the arithmetic processing unit starts recording the power value when the start condition is satisfied, and Recording of the power value may be stopped.

  The arithmetic processing unit may start recording the power value at a first time point and stop recording the power value at a second time point.

  A status signal input unit that receives a status signal indicating an operating status of the monitored device is further provided, and the arithmetic processing unit starts recording the power value when the status signal indicates that the monitored device is powered on. The recording of the power value may be stopped when the status signal indicates that the monitored device is powered off.

A state signal input unit for receiving a state signal indicating an operation state of the monitored device;
The arithmetic processing unit starts recording the power value when the status signal indicates an operation start of the monitored device, and the power value when the status signal indicates an operation stop of the monitored device. Recording may be stopped.

  The memory may store the start condition and the stop condition so as to be rewritable.

  An output unit capable of outputting the power value may be further included, and the arithmetic processing unit may record the power value in an external memory connected to the output unit.

  You may further provide the display part which displays the said electric power value.

1 is an external view showing an example of a power monitoring apparatus 100 according to a first embodiment. The block diagram which shows the structure of the electric power monitoring apparatus 100 according to 1st Embodiment. The figure which shows the connection relation of the electric power monitoring apparatus 100 and the to-be-monitored apparatus 200. FIG. The figure which shows the connection relation of the electric power monitoring apparatus 100 and the to-be-monitored apparatus 200. FIG. The block diagram which shows the structure of the power monitoring apparatus 300 by 2nd Embodiment. The figure which shows the screen of the display 51 of the power monitoring apparatus 400 by 3rd Embodiment. The block diagram which shows the structure of the power monitoring apparatus 500 by 4th Embodiment.

  Embodiments according to the present invention will be described below with reference to the drawings. This embodiment does not limit the present invention.

(First embodiment)
FIG. 1 is an external view showing an example of a power monitoring apparatus 100 according to the first embodiment. The power monitoring apparatus 100 is connected to the monitored apparatus in order to record the power consumption of the monitored apparatus such as a machine tool (see reference numeral 200 in FIGS. 3 and 4).

  The power monitoring apparatus 100 includes a housing 1, a power supply 2, a memory card slot 3, a data input unit 20, a status signal input unit 30, and a display 51. As shown in FIG. 2, a PLC (Programmable Logic Controller) 10 and the like are accommodated in the housing 1. The power monitoring apparatus 100 operates by receiving power supply from the power supply 2. The memory card slot 3 is configured so that, for example, a memory card such as an SD card can be inserted. The data input unit 20 receives the power value and the like of the monitored device from the monitored device. The status signal input unit 30 receives a status signal indicating the status of the monitored device. The status signal will be described later. The display 51 displays the power consumption of the monitored device.

  Although not shown in FIG. 1, the power monitoring apparatus 100 further includes a LAN (Local Area Network) port so that it can be connected to an external device such as a personal computer (hereinafter also simply referred to as a PC). Also good. Thereby, a plurality of power monitoring devices 100 may be connected to a host system (not shown) in a communicable manner, and the plurality of power monitoring devices 100 may be centrally managed in the host system.

  FIG. 2 is a block diagram showing a configuration of the power monitoring apparatus 100 according to the first embodiment. The power monitoring apparatus 100 includes a PLC 10 as an arithmetic processing unit, a data input unit 20, a state signal input unit 30, an external output unit 40, a display output unit 50, a memory 60, and a PC input / output unit 70. I have.

  The PLC 10 executes a sequence program stored in the memory 60, and thereby automatically controls each component of the power monitoring apparatus 10 in sequence. The sequence program is stored in the memory 60. When the PLC 10 executes the sequence program, the PLC 10 starts or stops recording of the power value consumed by the monitored device. The user can rewrite the sequence program in the memory 60 in order to set conditions for starting or stopping recording of the power value. At that time, the user rewrites the sequence program by operating an external PC (Personal Computer) connected to the PC input / output unit 70.

  The sequence program includes a start condition and a stop condition for recording the power value. The PLC 10 starts recording the power value of the monitored device when the start condition of the sequence program is satisfied, and stops recording the power value of the monitored device when the stop condition is satisfied. Note that the arithmetic processing unit may be configured by a general-purpose CPU (Central Processing Unit) and a program instead of the PLC 10 and the sequence program.

  As described above, the data input unit 20 receives a monitoring value such as power data of the monitored device. For example, when the monitored device is a machine tool, the monitored value is a value such as power consumed by the machine tool, voltage applied to the machine tool, current supplied to the machine tool, temperature or pressure of the processing unit. . More specifically, the power data input unit 21 receives a power value consumed (supplied) by the machine tool. The temperature input unit 22 receives temperature data of a machining unit of the machine tool. The voltage data input unit 23 receives a voltage value applied to the machine tool. The current data input unit 24 receives a current value supplied to the machine tool. Although not shown in FIG. 2, the data input unit 20 may further include a pressure input unit that receives pressure data of the machining unit of the machine tool.

  The power value is a value that can be calculated based on the voltage value and the current value. Therefore, the data input unit 20 may receive only the power value without receiving the voltage value and the current value. Thereby, PLC10 can record an electric power value as it is, or can display an electric power value on the display 51 as it is. That is, the PLC 10 does not need to calculate the power value from the voltage value and the current value. Conversely, the data input unit 20 may receive only the voltage value and the current value without receiving the power value. Thereby, PLC10 should just calculate an electric power value from a voltage value and an electric current value. In this case, the PLC 10 can record not only the power value but also the voltage value and the current value, or can display them on the display 51.

  The monitoring value may be stored in the internal memory 11 of the PLC 10. Alternatively, the monitoring value may be stored in an external memory inserted in the memory card slot 3. By using the external memory, the monitoring value data can be extracted from the power monitoring apparatus 100 without connecting an external PC to the power monitoring apparatus 100. Hereinafter, the description will be continued with the monitoring target as the power value.

  As described above, the status signal input unit 30 receives a status signal indicating the status of the monitored device. The status signal is a signal that serves as a trigger for the power monitoring apparatus 100 to start or stop monitoring the power of the monitored apparatus. For example, when the monitored device is a machine tool, the status signal is an I / O signal input / output from a sequencer (PLC) on the machine tool side. More specifically, the status signal may be a signal indicating an on state or an off state of a power supply of the machine tool. The state signal may be a signal indicating a state in which the machine tool has started machining (machining start signal) or a signal indicating a state in which machining is stopped (machining stop signal). The status signal may be a signal indicating the start or stop of rotation of a specific motor of the machine tool. The state signal may be a temperature at a predetermined location of the machine tool (for example, the temperature, the temperature of the motor, or the temperature of the machining portion). The status signal may be the flow rate of oil supplied to the sliding surface of the machine tool or the flow rate of coolant supplied to the machined portion of the machine tool. The status signal may be an on / off signal of a limit switch that is output when the operating part of the machine tool moves to a predetermined position. The status signal may be a machine tool emergency stop signal. When the machine tool is operated by the machining program and the CPU, the status signal may be a sequence number indicating each machining step of a predetermined machining program in the machine tool. When the machine tool is operated by a sequence program and a PLC, the status signal may be switching information (on / off) in ladder logic or ladder language. Further, the status signal may be a signal that informs of a malfunction or failure. These state signals are normally output from a control unit such as a PLC of a machine tool and can be easily taken out.

  The sequence number of the machining program of the machine tool indicates the order of the program steps executed by the CPU, and is different from the sequence program steps executed by the PLC.

  When these state signals satisfy a predetermined condition, the power monitoring apparatus 100 starts monitoring the power of the monitored apparatus, or when these state signals no longer satisfy the predetermined condition, What is necessary is just to stop monitoring of electric power. Specific start conditions and stop conditions for recording the power value will be described later.

  The external output unit 40 outputs a signal to the monitored device according to the power value. For example, when the power value exceeds a predetermined value, the external output unit 40 may output a signal for stopping the operation of the monitored device. The external output unit 40 may output the power value to the external PC. The external output unit 40 is communicatively connected to a monitored device or an external PC by, for example, a wired LAN or a wireless LAN.

  The display output unit 50 outputs the power value of the monitored device to the display 51. The display 51 displays the power value of the monitored device with a numerical value or a graph. Thereby, the user can easily grasp the power consumption of the monitored apparatus.

  3 and 4 are diagrams illustrating a connection relationship between the power monitoring apparatus 100 and the monitored apparatus 200. FIG. As shown in FIG. 3, the power monitoring apparatus 100 receives a voltage value and a current value (or power value) supplied from the power source to the monitored apparatus 200. In addition, the power monitoring apparatus 100 receives a status signal from the monitored apparatus 200.

  For example, when the monitored device 200 is a machine tool (hereinafter, also referred to as a machine tool 200), two power monitoring devices 100A and 100B may be connected to the machine tool 200 as shown in FIG. The power monitoring apparatus 100A receives a voltage value and a current value (or power value) supplied from the DC power supply of the machine tool 200 to the controller. Further, the power monitoring apparatus 100A receives a status signal from the controller of the machine tool 200. On the other hand, the power monitoring apparatus 100B receives a voltage value and a current value (or power value) supplied from the motor driver of the machine tool 200 to the motor M. In addition, the power monitoring apparatus 100B receives a status signal from the controller of the machine tool 200. The power monitoring devices 100A and 100B may receive the same status signal or may receive different status signals. For example, the power monitoring apparatus 100A may receive a status signal indicating whether the power of the machine tool 200 is turned on or off, and the power monitoring apparatus 100B may receive a status signal indicating whether the motor M is driven.

  The power monitoring devices 100A and 100B start recording the power value of the machine tool 200 based on the status signals, respectively, or stop the recording. When the power monitoring devices 100A and 100B receive different status signals, the power monitoring devices 100A and 100B start recording the power value of the machine tool 200 at different timings, or stop the recording. On the other hand, when the power monitoring devices 100A and 100B receive the same status signal, the power monitoring devices 100A and 100B can simultaneously start recording the power value of the machine tool 200 or stop the recording.

  Next, specific examples of the power value recording start condition and stop condition will be described.

(Status signal: Power on / off)
When the status signal is a signal indicating the power-on state or off-state of the monitored device 200, the PLC 10 records the power value of the monitored device 200 when the status signal indicates that the monitored device 200 is powered on. To start. Further, the PLC 10 stops recording the power value of the monitored device 200 when the status signal indicates that the monitored device 200 is powered off. As described above, the power value recording start condition and stop condition may be power-on and power-off of the monitored apparatus 200, respectively.

  The user can set the start condition and the stop condition for recording the power value in the sequence program in the memory 60. As a result, the power monitoring apparatus 100 can automatically start recording the power value when the monitored apparatus 200 is turned on, and can automatically stop recording the power value when the monitored apparatus 200 is turned off. it can.

  During the period when the monitored device 200 is not powered on, the power monitoring device 100 does not record the power of the monitored device 200. Therefore, the power monitoring apparatus 100 can reduce the capacity of data stored in the memory 11 or the external memory without being operated by the operator. Moreover, since the power monitoring apparatus 100 does not record unnecessary data, the analysis time can be shortened when analyzing the power of the monitored apparatus 200.

(Status signal: Machining start signal / machining stop signal)
When the status signal is a signal indicating start / stop of machining of the machine tool 200, the PLC 10 starts recording the power value of the monitored device 200 when the status signal indicates machining start. Further, the PLC 10 stops the recording of the power value of the monitored apparatus 200 when the status signal indicates that processing is stopped. As described above, the start condition and the stop condition for recording the electric power value may be the machining start and the machining stop of the machine tool 200, respectively. Thereby, the power monitoring apparatus 100 can automatically start recording the power value simultaneously with the start of machining of the machine tool 200 and can automatically stop recording of the power value simultaneously with the start of machining of the machine tool 200.

  During the period when the machine tool 200 stops processing, the power monitoring apparatus 100 does not record the power of the machine tool 200. Therefore, the power monitoring apparatus 100 can reduce the capacity of data stored in the memory 11 or the external memory without being operated by the operator. Further, since the power monitoring apparatus 100 does not record unnecessary data, the analysis time can be shortened when analyzing the power of the machine tool 200.

  The machining start / machining stop may mean the start / stop of the machining program execution in the machine tool 200. Alternatively, the machining start / machining stop may mean that the motor M of the machine tool 200 actually starts rotating or stops rotating.

(Status signal: Temperature)
When the status signal is the temperature of a predetermined portion of the machine tool 200, the PLC 10 starts recording the power value of the monitored apparatus 200 when the temperature of the predetermined portion exceeds a predetermined value. Moreover, PLC10 stops the recording of the electric power value of the to-be-monitored apparatus 200, when the temperature of the predetermined part falls below a predetermined value. As described above, the start condition and the stop condition for recording the power value may be the temperatures of predetermined portions of the machine tool 200, respectively.

  The predetermined temperature value is set in the sequence program in the memory 60. The temperature of the predetermined part of the machine tool 200 may be the ambient temperature around the machine tool 200, the temperature of the motor M, the temperature of the tool that comes into contact with the workpiece, and the like. These temperatures can be measured by a thermistor thermometer or the like provided in the machine tool 200. Thereby, the power monitoring apparatus 100 can automatically start recording the power value when a predetermined portion of the machine tool 200 is abnormally heated. That is, in this case, the power monitoring apparatus 100 can record the power when the machine tool 200 is abnormal.

  When the machine tool 200 is operating normally and the temperature of the predetermined portion is lower than the predetermined value, the power monitoring apparatus 100 does not record the power of the machine tool 200. Therefore, the power monitoring apparatus 100 can reduce the capacity of data stored in the memory 11 or the external memory. Further, since the power monitoring apparatus 100 does not record unnecessary data, the analysis time can be shortened when analyzing the abnormality of the machine tool 200.

(Status signal: Oil supply or coolant supply)
When the status signal is the oil supply amount or coolant supply amount of the machine tool 200, the PLC 10 starts recording the power value of the monitored device 200 when the oil or coolant supply amount falls below a predetermined value. Further, the PLC 10 stops recording the power value of the monitored device 200 when the supply amount of oil or coolant exceeds a predetermined value. As described above, the start condition and the stop condition for recording the power value may be the oil supply amount or the coolant supply amount of the machine tool 200.

  When the supply amount of oil or coolant is small, the frictional resistance and temperature of the machined part of the machine tool 200 may become abnormally high. Therefore, the power monitoring apparatus 100 can record the power when the machine tool 200 is abnormal by setting the start value of the recording of the power value that the supply amount of oil or coolant is below a predetermined value.

  When the supply amount of oil or coolant exceeds a predetermined value, the frictional resistance and temperature of the machined part of the machine tool 200 do not increase, and the machine tool 200 can operate normally. Therefore, the power monitoring apparatus 100 can reduce the capacity of data stored in the memory 11 or the external memory by setting the stop condition for recording the power value that the supply amount of oil or coolant exceeds a predetermined value. . Further, since the power monitoring apparatus 100 does not record unnecessary data, the analysis time can be shortened when analyzing the abnormality of the machine tool 200.

(Status signal: Limit switch on / off)
When the status signal is a signal indicating ON / OFF of the limit switch of the machine tool 200, the limit switch moves the operation part of the machine tool 200 (for example, a spindle cradle) to a predetermined position (first position). When the operation part of the machine tool 200 moves to another predetermined position (second position), it can be configured to be turned off. In this case, the PLC 10 starts recording the power value of the monitored apparatus 200 when the operating part of the machine tool 200 moves to the first position. Moreover, PLC10 stops the recording of the electric power value of the to-be-monitored apparatus 200, when the operation | movement part of the machine tool 200 moves to the 2nd position. As described above, the start condition and the stop condition for recording the power value may be ON / OFF of the limit switch of the machine tool 200, respectively. Thereby, the power monitoring apparatus 100 can automatically start or stop recording of the power value according to the position of the operating portion of the machine tool 200. Therefore, the power monitoring apparatus 100 can reduce the capacity of data stored in the memory 11 or the external memory. Further, since the power monitoring apparatus 100 does not record unnecessary data, the analysis time can be shortened when analyzing the power of the machine tool 200.

(Status signal: Emergency stop signal)
When the status signal is an emergency stop signal of the machine tool 200, the PLC 10 stops recording the power value of the monitored device 200 when the machine tool 200 is operating normally. However, when the machine tool 200 issues an emergency stop signal, recording of the power value of the monitored apparatus 200 is started. Thereby, the power monitoring apparatus 100 can automatically start recording the power value when the machine tool 200 is abnormal. That is, in this case, the power monitoring apparatus 100 can record the power when the machine tool 200 is abnormal.

  When the machine tool 200 is operating normally, the power monitoring apparatus 100 does not record the power of the machine tool 200. Therefore, the power monitoring apparatus 100 can reduce the capacity of data stored in the memory 11 or the external memory. Further, since the power monitoring apparatus 100 does not record unnecessary data, the analysis time can be shortened when analyzing the abnormality of the machine tool 200.

  As described above, the power monitoring apparatus 100 according to the present embodiment can automatically start recording the power value of the monitored apparatus 200 according to a predetermined condition, and can automatically end the recording of the power value. Thereby, the power monitoring apparatus 100 can measure and record data necessary for analyzing the power consumption of the monitored apparatus 200 and can reduce the data capacity recorded in the memory.

  In addition, the power monitoring apparatus 100 according to the present embodiment can be easily externally attached to the monitored apparatus 200 after the monitored apparatus 200 is installed without changing the internal configuration of the monitored apparatus 200. Therefore, this embodiment can add a power monitoring function to the installed monitored apparatus 200 relatively easily and at low cost.

(Second Embodiment)
FIG. 5 is a block diagram illustrating a configuration of the power monitoring apparatus 300 according to the second embodiment. In the second embodiment, the status signal is a sequence signal (for example, sequence number, program content) indicating each machining step of the machining program of the machine tool. Alternatively, when the machine tool operates with a sequence program and a PLC, switching information (on / off) in ladder logic or ladder language may be used. Therefore, the power monitoring apparatus 300 includes a sequence signal input unit 32 and a sequence signal output unit 34.

  The power monitoring apparatus 300 is sequence-controlled by the PLC 10 executing a sequence program stored in the memory 60. The PLC 10 compares the sequence signal preset in the sequence program with the sequence signal received from the machine tool, and starts or stops the recording of the power value. Therefore, the power monitoring apparatus 300 includes the sequence signal input unit 32 for receiving the first sequence signal from the machine tool. Further, the power monitoring apparatus 300 may output a control signal as a second sequence signal to the machine tool based on the power value. Therefore, the power monitoring apparatus 300 includes a sequence signal output unit 34 for outputting a sequence signal to the machine tool. That is, the power monitoring apparatus 300 according to the second embodiment further includes a sequence signal input unit 32 that receives a sequence signal from the machine tool, and a sequence signal output unit 34 that outputs the sequence signal to the machine tool. Other configurations of the power monitoring apparatus 300 may be the same as the corresponding configurations of the power monitoring apparatus 100.

  The state signal input unit 30 shown in FIG. 2 may be provided together with the sequence signal input unit 32, but may be omitted. The connection relationship between the power monitoring apparatus 300 and the machine tool may be the same as the connection relationship shown in FIG. 3 or FIG.

  The machining program of the machine tool is set so as to execute a plurality of machining steps sequentially in a predetermined order. Each machining step of the machining program is configured in order of execution by a sequence number. When the PLC of the machine tool executes the machining steps according to the sequence number, the machine tool operates to machine the workpiece to a desired shape.

  The power monitoring apparatus 300 incorporates a sequence program separately from the machine tool and is sequence-controlled. The sequence program for the power monitoring apparatus 300 is stored in the memory 60.

  The PLC 10 of the power monitoring apparatus 300 executes the sequence program of the power monitoring apparatus 300. Thereby, the power monitoring apparatus 300 can start or stop recording the power value of the machine tool. In the sequence program of the power monitoring apparatus 300, a start condition and a stop condition for recording the power value are set in advance. Note that the user can change the start condition and the stop condition for recording the power value when rewriting the sequence program in the memory 60 using the external PC.

  The power monitoring apparatus 300 can receive a machine tool sequence signal (hereinafter also referred to as a first sequence signal) as a status signal via the sequence signal input unit 32, as in the first embodiment. The PLC 10 compares the sequence signal preset in the sequence program in the memory 60 with the first sequence signal, and determines whether or not the first sequence signal meets the start condition or the stop condition for recording the power value. Judging. A specific example of the start condition or the stop condition for recording the power value is the same as the specific example shown in the first embodiment. For example, the first sequence signal may be a signal indicating the power state of the machine tool. In this case, the PLC 10 starts recording the power value when the first sequence signal indicates that the machine tool is turned on. On the other hand, the PLC 10 stops recording the power value when the first sequence signal indicates that the machine tool is turned off.

  The first sequence signal may be a machining start signal or a machining stop signal of the machine tool. In this case, the PLC 10 starts recording the power value when the first sequence signal indicates the start of the machining operation of the machine tool. On the other hand, the PLC 10 stops the recording of the power value when the first sequence signal indicates that the machining operation of the machine tool is stopped.

  The first sequence signal may be a signal indicating the rotation start or rotation stop of the motor M. In this case, the PLC 10 starts recording the power value when the first sequence signal indicates the start of rotation of the motor. On the other hand, the PLC 10 stops recording the power value when the first sequence signal indicates that the motor has stopped rotating.

  The PLC 10 may determine the start condition or the stop condition for recording the power value based on the sequence number of the first sequence signal. In this case, the user may set the start condition or the stop condition for recording the power value in the sequence program of the power monitoring apparatus 300 with the sequence number of the machining program on the machine tool side. The PLC 10 compares the sequence number preset in the sequence program of the power monitoring apparatus 300 with the sequence number of the first sequence signal. When these sequence numbers match, the PLC 10 starts or stops recording of the power value.

  Alternatively, the PLC 10 may determine the start condition or the stop condition for recording the power value based on the program content (command content) of the processing step corresponding to the first sequence signal. In this case, the user may set the start condition or the stop condition for recording the power value in the sequence program of the power monitoring apparatus 300 with the instruction content of the first sequence signal. The PLC 10 compares the command content set by the sequence program of the power monitoring apparatus 300 with the command content of the first sequence signal. The PLC 10 may start or stop recording the power value when the contents of these instructions match.

  The power monitoring apparatus 300 can also output a sequence signal (hereinafter also referred to as a second sequence signal) to the machine tool via the sequence signal output unit 34. The second sequence signal may be a signal for controlling the operation of the machine tool. For example, when the power consumption of the machine tool is higher than a predetermined value, in order to reduce the power consumption, the second sequence signal changes a part or all of the machining program of the machine tool to another machining program. It may be a signal. Thereby, the power monitoring apparatus 300 can not only monitor the power consumption of the machine tool but also change the operation of the machine tool according to the power consumption.

  The power monitoring apparatus 300 according to the second embodiment has the sequence number of the machining program for the machine tool or the program content itself as the start condition or stop condition for recording the power value. Therefore, the power monitoring apparatus 300 can start or stop the recording of the power consumption of the machine tool using the sequence signal of the machine tool as the status signal. Thereby, 2nd Embodiment can reduce the capacity | capacitance of the data stored in the memory 11 or an external memory. Further, since the second embodiment does not record unnecessary data, the analysis time can be shortened when analyzing the power consumption of the machine tool. The second embodiment can also obtain other effects of the first embodiment.

(Third embodiment)
FIG. 6 is a diagram illustrating a screen of the display 51 of the power monitoring apparatus 400 according to the third embodiment. Other configurations of the power monitoring apparatus 400 according to the third embodiment may be the same as the corresponding configurations of the power monitoring apparatus 100 illustrated in FIG. 2 or the power monitoring apparatus 300 illustrated in FIG. 5.

  In the third embodiment, the display output unit 50 outputs the table T and the graph G, and the display 51 displays the table T and the graph G. The table T displays the power value so as to correspond to the machining program of the machine tool 200. The graph G displays a line L indicating the power value consumed in the machine tool 200 in real time, and an average value A of power consumption at the sequence number of each machining step. In addition, the vertical axis | shaft of the graph G shows the power consumption in the machine tool 200, and the horizontal axis shows time.

  The table T indicates the sequence number of the machining step of each machining step executed in the machine tool 200, the contents of the machining program of each machining step, and the average value (power average value) of power consumption in each machining step. . The content of the machining program includes information such as an operation command of the machine tool 200 and coordinates necessary for executing the operation. The power average value is an average value of power consumed by the machine tool in each machining step. The average power value in the table T corresponds to the average value A in the graph G.

  A line L of the graph G displays power consumption in real time. For this reason, the electric power average value A is displayed after execution of each processing step.

  The sequence signal received as a status signal by the power monitoring apparatus 400 may be either the sequence number of the machining step and / or the program content. Therefore, the power monitoring apparatus 400 according to the third embodiment can cause the sequence number, program content, and power consumption in each machining step of the machining program of the machine tool 200 to correspond to each other and simultaneously output to the display 51 for display. . Thereby, the operator can easily grasp the processing steps with high power consumption by referring to the display 51. It is possible to contribute to energy saving of the machine tool by changing or correcting the machining step program with high power consumption to a machining step with relatively low power consumption. For example, according to the power monitoring apparatus 400, the user consumes a method (method 1) for machining a machining object with a small number of times by heavy cutting and a method (method 2) for machining a machining object by a large number of times by light cutting. It can be easily compared in power.

  The power monitoring apparatus 400 outputs or displays the power consumption in each processing step in real time. Therefore, the operator can know the abnormality of the machine tool and the excessive power consumption in real time, and thereby can immediately cope with the abnormality of the machine tool and the excessive power consumption.

  The power monitoring apparatus 400 can display the processing step sequence number, program content, and power consumption on the display 51 and simultaneously store them in the memory 11. The display output unit 50 may output parameters other than the sequence number of the processing step, the program content, and the power value to the display 51. For example, an integrated value of power consumption (total power consumption until the processing step), an average value of power consumption until the processing step, and the like may be displayed on the display 51.

  Other operations of the power monitoring apparatus 400 according to the third embodiment may be the same as the operations of the power monitoring apparatus according to the first or second embodiment. Therefore, when the program of the power monitoring apparatus 400 includes the start condition and stop condition for recording the power value as in the first or second embodiment, the display output unit 50 sets the stop condition after satisfying the start condition. What is necessary is just to output the electric power value until it satisfy | fills. Moreover, the display 51 should just display the electric power value after satisfy | filling stop conditions after satisfy | filling start conditions. Thus, the third embodiment can be combined with the first or second embodiment.

  The display 51 does not necessarily have to be provided in the power monitoring apparatus 400. In this case, the power monitoring apparatus 400 outputs information indicating the machining program of the machine tool (first sequence signal) and the power value in association with each other to the external PC or the like via the external output unit 40. Also good. Thereby, the power monitoring apparatus 400 can display the table T and the graph G on a display such as an external PC. In this case, the power monitoring apparatus 400 does not need the display output unit 50 and the display 51, and may include the external output unit 40 illustrated in FIG.

(Fourth embodiment)
FIG. 7 is a block diagram illustrating a configuration of a power monitoring apparatus 500 according to the fourth embodiment. In the fourth embodiment, the PLC 10 further includes a timer 12. Then, the PLC 10 starts recording the power value at the first time point and stops recording the power value at the second time point. That is, the PLC 10 does not start / stop recording the power value based on the status signal received from the monitored apparatus, but starts / stops recording the power value based on the timer 12 in the PLC 10. Therefore, in the fourth embodiment, the state signal input unit 30 (or the sequence input 32) may be omitted.

  Of course, the fourth embodiment may be combined with the third embodiment. That is, the power monitoring device may output the power value of the monitored device from the first time point to the second time point, and display the power value on the display 51 or an external display.

  When the user wants to analyze the power consumption of the monitored apparatus in a certain time zone, the power monitoring apparatus 500 according to the fourth embodiment can measure and record only data necessary for analyzing the power consumption of the monitored apparatus. it can. Therefore, the data capacity recorded in the memory can be reduced, and the power consumption analysis time can be shortened.

  The fourth embodiment may be combined with the first to third embodiments. For example, when the fourth embodiment is combined with the first or second embodiment, the power monitoring apparatus 100 receives a state signal from the monitored apparatus at the state signal input unit 30. When the status signal satisfies the power value recording start condition, the PLC 10 records the power consumption of the monitored apparatus. At that time, the timer 12 starts measuring time. Then, after a predetermined time has elapsed since the recording of the power value was started (for example, 1 hour later), the PLC 10 ends the recording of the power consumption of the monitored apparatus. That is, the start of recording of the power value is determined by the status signal of the monitored apparatus, and the end of recording of the power value is determined by the time of the timer 12. Thereby, the power monitoring apparatus can record, output, or display the power consumption of the monitored apparatus within a predetermined period after the monitored apparatus enters a predetermined state. Even if it does in this way, the effect of the present invention can be acquired.

100, 300, 400, 500 ... power monitoring device, 1 ... housing, 2 ... power supply, 3 ... memory card slot, 10 ... PLC, 11 ... memory, 12 ... Timer 20 ... Data input unit 30 ... Status signal input unit 40 ... External output unit 50 ... Display output unit 51 ... Display 60 ... Memory 70 ..PC input / output section

Claims (8)

A data input unit that receives a power value consumed in the monitored device or a voltage value and a current value supplied to the monitored device;
A memory for storing a program for starting or stopping recording of the power value or recording of the power value calculated based on the voltage value and the current value;
A power monitoring apparatus comprising: an arithmetic processing unit that starts or stops recording of the power value according to the program. The program includes a start condition and a stop condition for recording the power value,
The said arithmetic processing part starts the recording of the said electric power value when the said start condition is satisfy | filled, and stops the recording of the said electric power value when the said stop condition is satisfy | filled. Power monitoring device.   3. The power monitoring according to claim 1, wherein the arithmetic processing unit starts recording the power value at a first time point and stops recording the power value at a second time point. apparatus. A state signal input unit for receiving a state signal indicating an operation state of the monitored device;
The arithmetic processing unit starts recording the power value when the status signal indicates that the monitored device is powered on, and the power value when the status signal indicates that the monitored device is powered off. The power monitoring apparatus according to any one of claims 1 to 3, wherein recording of the power is stopped. A state signal input unit for receiving a state signal indicating an operation state of the monitored device;
The arithmetic processing unit starts recording the power value when the status signal indicates an operation start of the monitored device, and the power value when the status signal indicates an operation stop of the monitored device. The power monitoring apparatus according to any one of claims 1 to 3, wherein recording of the power is stopped.   The power monitoring apparatus according to any one of claims 2 to 5, wherein the memory stores the start condition and the stop condition so as to be rewritable. An output unit capable of outputting the power value;
7. The power monitoring apparatus according to claim 1, wherein the arithmetic processing unit records the power value in an external memory connected to the output unit.   The power monitoring apparatus according to claim 1, further comprising a display unit that displays the power value.

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