JP5431511B2 - Demand monitoring system - Google Patents

Description

  The present invention relates to a demand monitoring device that issues a warning when a maximum demand power exceeding a contract power is predicted while constantly monitoring the maximum demand power, and a test at the time of installation or an inspection after the installation. The present invention relates to a demand monitoring system.

  As a watt hour meter installed in a high voltage power receiving electric power consumer, one that measures the amount of power used for 30 minutes is used. The average used power obtained from the measured value of the watt-hour meter is set as a 30-minute demand value, and the maximum 30-minute demand value in one month is set as the maximum demand power (maximum demand value) of the month.

  In this high voltage power receiving power consumer, the largest value of the maximum demand power of the month and the past 11 months is used for the calculation of the basic charge. The contract power will be changed. For this reason, power consumers who receive high-voltage power are installed with a demand monitoring device that issues a warning when the maximum demand power exceeding the contract power is predicted due to the use of high load power, etc. while constantly monitoring the maximum power demand. (For example, refer to Patent Document 1).

  The demand monitoring device disclosed in Patent Document 1 calculates a power demand prediction at the end of a demand cycle based on the amount of power used up to the present when the current operation state is a steady operation, and calculates a high load power. When the specific operation is used for a certain period, the power demand prediction is calculated based on the amount of power used up to the present time for the specific operation period, and after the specific operation period has elapsed, the power is calculated based on preset constants related to steady operation. By calculating the demand prediction, a power demand prediction calculation unit that calculates the power demand prediction at the end of the demand cycle, and an alarm is output when the calculated power demand prediction exceeds the stored power demand upper limit value An alarm output unit is provided.

JP 2011-61991 A

  By the way, when the demand monitoring device disclosed in Patent Document 1 is newly installed in a high voltage power receiving power consumer, it is desirable to perform a performance test as to whether or not the demand monitoring device operates normally. Further, even after the demand monitoring device is installed in a power consumer who receives high-voltage power, an abnormality in the demand value displayed on the demand monitoring device may occur. In such a case, it is desirable to inspect the demand monitoring device in order to determine whether the abnormality is in the demand monitoring device main body or due to the influence of the installation environment of the demand monitoring device.

  However, since there is no device for confirming the operation of the demand monitoring device described above, a performance test is performed as to whether the demand monitoring device operates normally, whether the demand monitoring device is abnormal, or The current situation is that the demand monitoring apparatus cannot be inspected in order to determine whether it is abnormal due to the influence of the installation environment of the demand monitoring apparatus. Therefore, it has been demanded that the demand monitoring device can be tested at the time of installation or inspection after the installation.

  Therefore, the present invention has been proposed in view of the above-mentioned demand, and the object of the present invention is to provide demand monitoring that can easily perform a test at the time of installation or an inspection after the installation of a demand monitoring device by a simple means. To provide a system.

As a technical means for achieving the above-described object, the demand monitoring system according to the present invention constantly monitors the maximum demand power based on the measurement pulse output from the watt-hour meter installed in the power consumer receiving high voltage power. A demand monitoring system that performs a test at the time of installation or an inspection after installation for a demand monitoring device that is connected to the demand monitoring device removed from the watt hour meter and is equivalent to a metering pulse output from the watt hour meter A demand pulse output device that generates a metering pulse in a pseudo manner and sends the pseudo metering pulse to a demand monitoring device, and an alarm that is connected to the demand monitoring device and connected to the demand pulse output device according to the demand power is composed of a display device for displaying the status, this was a metering pulses output from the demand pulse output device so as to variably The features. Here, the “metering pulse” means a signal having the number of pulses corresponding to the amount of power as a measured value measured by the watt hour meter.

  In the present invention, when a demand monitoring device is installed, a performance test is performed to determine whether or not the demand monitoring device operates normally, or whether the demand monitoring device main body is abnormal after the demand monitoring device is installed. In order to determine whether the abnormality is caused by the influence of the installation environment of the demand monitoring apparatus, when the inspection is performed on the demand monitoring apparatus, first, the input of the demand monitoring apparatus is removed from the output of the watt-hour meter.

  Then, a demand pulse output device that artificially generates a measurement pulse equivalent to the measurement pulse output from the watt hour meter is connected to the demand monitoring device removed from the watt hour meter. In addition, a display device that displays an alarm state corresponding to the demand power is connected to the demand monitoring device and the demand pulse output device.

  In this way, by sending the pseudo metering pulse generated by the demand pulse output device to the demand monitoring device, the state is equivalent to the case of sending the metering pulse output from the watt hour meter to the demand monitoring device. By setting, when the demand monitoring apparatus is installed, a performance test can be performed as to whether or not the demand monitoring apparatus operates normally. In addition, after installing the demand monitoring device, it is also possible to inspect the demand monitoring device to determine whether it is an abnormality of the demand monitoring device itself or due to the influence of the installation environment of the demand monitoring device It becomes.

  The watt hour meter in the present invention outputs a timed pulse in addition to the metering pulse, and the demand pulse output device artificially generates a metering pulse and a timed pulse equivalent to the metering pulse and the timed pulse output from the power meter. However, the present invention can also be applied to the case where the pseudo measurement pulse and the timed pulse are transmitted to the demand monitoring device. Here, the “timed pulse” means a signal having the number of pulses corresponding to the time for obtaining the demand value from the electric energy as the measurement value measured by the watt-hour meter.

  In the demand pulse output device according to the present invention, it is desirable to be able to select a menu mode, a calibration mode, a variable mode, a display mode, and an operation confirmation mode. As described above, if the menu mode, the calibration mode, and the variable mode can be selected, various conditions for outputting the pseudo timed pulse and the measurement pulse can be easily set. In addition, if the display mode and the operation confirmation mode can be selected, the control state of the demand monitoring device and the load device can be confirmed.

  In the menu mode of the demand pulse output device according to the present invention, it is desirable that the transformation ratio can be set so as to output a measurement pulse corresponding to the type of watt-hour meter. In this way, the transformation ratio in the demand pulse output device can be matched with the transformation ratio in the watt hour meter, and the demand monitoring device to which the demand pulse output device is connected operates in the same manner as when connected to the watt hour meter. Can be made.

  In the calibration mode of the demand pulse output device according to the present invention, it is desirable to be able to select a pulse constant according to the type of watt-hour meter. In this way, the measurement pulse in the demand pulse output device can be matched with the measurement pulse output by the watt hour meter, and the demand monitoring device to which the demand pulse output device is connected is the same as when connected to the watt hour meter. Can be operated.

  In the variable mode of the demand pulse output device according to the present invention, it is desirable to be able to select a pulse constant according to the type of watt hour meter and to change the amount of power when an alarm is issued by the demand monitoring device. In this way, the measurement pulse in the demand pulse output device can be matched with the measurement pulse output by the watt hour meter, and the demand monitoring device to which the demand pulse output device is connected is the same as when connected to the watt hour meter. Can be operated. In addition, the amount of power when an alarm is issued by the demand monitoring device can be set to an arbitrary value.

  In the display mode of the demand pulse output device according to the present invention, by automatically changing the measurement pulse output from the demand pulse output device, an alarm state corresponding to the measurement pulse is output from the demand monitoring device to the display device. In addition, it is desirable that a series of operations output from the display device to the demand pulse output device can be repeated for each variable measurement pulse. In this way, it is possible to confirm whether the display operation and the control operation of the demand monitoring device are normally repeated.

  The operation check mode of the demand pulse output device in the present invention outputs a measurement pulse corresponding to the limit demand power or more from the demand pulse output device, detects the slope of the increase in power at the midpoint of the demand cycle with the demand monitoring device, The demand demand power corresponding to the slope of the increase in power is measured by the demand monitoring device. Based on the predicted demand power, the load device connected to the output of the demand monitoring device is set to be equal to or lower than the target demand power at the end of the demand cycle. It is desirable to control so that it becomes. In this way, it is possible to confirm whether or not the load device is normally controlled so as to be equal to or less than the target demand power at the end of the demand cycle.

  In the present invention, the demand monitoring device measures a demand value and an integrated measurement value corresponding to a pseudo measurement pulse output from the demand pulse output device, and a memory for recording the demand value and the integrated measurement value is built in the demand monitoring device. Desirable structure is desirable. In this way, it is possible to confirm whether or not the demand value and the integrated measurement value corresponding to the pseudo measurement pulse are accurately measured by the demand monitoring device.

  In the present invention, a structure in which the demand pulse output device and the demand monitoring device are integrated is desirable. In this way, the demand monitoring system can be made compact.

  According to the present invention, a performance test is performed on whether or not the demand monitoring device operates normally when the demand monitoring device is installed by sending a pseudo measurement pulse generated by the demand pulse output device to the demand monitoring device. Can be implemented. In addition, after installing the demand monitoring device, it is also possible to inspect the demand monitoring device to determine whether it is an abnormality of the demand monitoring device itself or due to the influence of the installation environment of the demand monitoring device It is. In this way, a demand monitoring apparatus with high reliability can be provided by easily performing a test at the time of installation or an inspection after the installation with respect to the demand monitoring apparatus by simple means.

1 is a configuration diagram illustrating a state in which a demand pulse output device and a display device are connected to a demand monitoring device in an embodiment of a demand monitoring system according to the present invention. It is a block diagram which shows the state which connected the demand monitoring apparatus to the watt-hour meter installed in the electric power consumer of the high voltage electric power reception, and connected the load apparatus to the demand monitoring apparatus. It is a functional block diagram for demonstrating the menu mode in a demand pulse output device, a calibration mode, a variable mode, and an operation confirmation mode. It is a functional block diagram for demonstrating the display mode in a demand pulse output device. It is a table | surface which shows the metamorphosis ratio in menu mode. It is a table | surface which shows the electric energy in the alarm state in display mode. It is a graph for demonstrating the system operation | movement in display mode. It is a graph for demonstrating the system operation | movement in operation check mode.

  An embodiment of a demand monitoring system according to the present invention will be described in detail below. 1 shows the overall configuration of the demand monitoring system in a state where the demand pulse output device 13 and the display device 14 are connected to the demand monitoring device 12 removed from the watt-hour meter 11, and FIG. A state in which the output device 13 (see FIG. 1) is not connected, that is, an operating state of the demand monitoring device 12 connected to the watt hour meter 11 is shown.

  As shown in FIG. 2, a watt hour meter 11 is connected to an AC three-phase 6600 V distribution line 15 via a meter transformer 16 (VT) and a current transformer 17 (CT), and the output of the watt hour meter 11 Is connected to the demand monitoring device 12. A load device 18 such as an air conditioning equipment to be controlled is connected to the output of the demand monitoring device 12. As the watt-hour meter 11 installed in a high-voltage power receiving power consumer, one that measures the amount of power used for 30 minutes is used. The average used power obtained from the measured value of the watt-hour meter 11 is set as a 30-minute demand value, and the maximum 30-minute demand value in one month is set as the maximum demand power (maximum demand value) of the month.

  In this high voltage power receiving power consumer, the largest value of the maximum demand power of the month and the past 11 months is used for the calculation of the basic charge. The contract power will be changed. For this reason, the demand monitoring device 12 that issues a warning when the electric power consumer receiving high-voltage power constantly monitors the maximum demand power and the occurrence of the maximum demand power exceeding the contract power due to the use of high load power or the like is predicted. Connected to the watt hour meter 11.

  The demand monitoring device 12 constantly monitors the maximum demand power based on the timed pulse and the metering pulse output from the watt hour meter 11, and predicts the occurrence of the maximum demand power exceeding the contract power due to the use of high load power, for example. For example, a three-stage alarm signal consisting of “margin”, “caution”, and “limit” is output to the load device 18 step by step. As an example, when the alarm state is “margin”, the load device 18 is operated 100%, when the alarm state is “caution”, the load device 18 is operated 70%, and when the alarm state is “limit”. Controls the load device 18 to operate (stop) 0%. The demand monitoring device measures a demand value (kW) and an integrated measurement value (kWh) based on the timed pulse and the measurement pulse output from the watt hour meter 11, and the demand value (kW) and the integrated measurement value. (KWh) is displayed on a display unit such as a liquid crystal display.

  Here, when the demand monitoring apparatus 12 is newly installed in a power consumer receiving high voltage power, it is desired to perform a performance test as to whether or not the demand monitoring apparatus 12 operates normally. Further, even after the demand monitoring device 12 is installed in a power consumer receiving high voltage power, an abnormality in the demand value displayed on the demand monitoring device 12 may occur. In such a case, it is desired to inspect the demand monitoring device 12 in order to determine whether it is an abnormality of the demand monitoring device 12 main body or an abnormality due to the influence of the installation environment of the demand monitoring device 12. Yes.

  Therefore, when the demand monitoring device 12 is installed, a performance test is performed as to whether or not the demand monitoring device 12 operates normally, or after the demand monitoring device 12 is installed, an abnormality of the demand monitoring device 12 itself is detected. In order to determine whether there is an abnormality due to the influence of the installation environment of the demand monitoring apparatus 12 or when the demand monitoring apparatus 12 is inspected, as shown in FIG. Is removed from the output of the watt hour meter 11. At this time, the operation state of the load device 18 can also be confirmed by performing the performance test and inspection of the demand monitor device 12 with the load device 18 connected to the demand monitor device 12. When it is not necessary to check the operation state of the load device 18, it is possible to perform a performance test or inspection of the demand monitor device 12 with the load device 18 removed from the demand monitor device 12.

  In addition, a demand pulse output device 13 that artificially generates a time pulse and a metering pulse equivalent to the time pulse and metering pulse output from the watt hour meter 11 is removed from the watt hour meter 11. Connect to. In addition, the demand monitoring device 12 and the demand pulse output device 13 are provided with a display device 14 that displays in a stepwise manner an alarm state corresponding to demand power, that is, three alarm states consisting of “margin”, “caution”, and “limit”. Connecting.

  In this way, by sending the pseudo timed pulse and the metering pulse generated by the demand pulse output device 13 to the demand monitoring device 12, the timed pulse and the metering pulse output from the watt hour meter 11 are transmitted to the demand monitoring device. When the demand monitoring device 12 is installed, a performance test can be performed to determine whether or not the demand monitoring device 12 operates normally. . Further, after the demand monitoring device 12 is installed, the demand monitoring device 12 is inspected to determine whether the demand monitoring device 12 is abnormal or due to the influence of the installation environment of the demand monitoring device 12. It is also possible to do. In this way, the demand monitoring device 12 can be provided with high reliability by easily performing the test at the time of installation or the inspection after the installation with respect to the demand monitoring device 12 by simple means.

  In the demand pulse output device 13 described above, the menu mode, calibration mode, variable mode, operation confirmation mode (see FIG. 3) and display mode (see FIG. 4) can be selected by button operation. As described above, since the menu mode, the calibration mode, and the variable mode can be selected, various conditions for outputting the timed pulse and the measuring pulse equivalent to the timed pulse and the measuring pulse output from the watt hour meter 11 can be easily obtained. Can be set to Further, since the display mode and the operation confirmation mode can be selected, the control states of the demand monitoring device 12 and the load device 18 can be confirmed. The demand pulse output device 13 includes a button for selecting a menu mode, a calibration mode, a variable mode, a display mode, and an operation confirmation mode, as well as a selected mode and a measurement pulse to be output to the demand monitoring device 12. A display unit such as a liquid crystal display that displays a corresponding amount of power is provided.

  In the menu mode of the demand pulse output device 13, as shown in FIG. 3, the transformation ratio (VT ratio × CT ratio) can be set by operating a button so that a measurement pulse corresponding to the type of the watt hour meter 11 is output. Yes. By setting this transformation ratio, the transformation ratio in the demand pulse output device 13 can be matched with the transformation ratio in the watt hour meter 11, and the demand monitoring device 12 to which the demand pulse output device 13 is connected is connected to the watt hour meter 11. It can be operated in the same manner as in

  Here, the secondary voltage of the instrument transformer 16 (VT) measured from the distribution line 15 (see FIGS. 1 and 2) is AC110V, and the secondary current of the current transformer 17 (CT) is AC5A. . Therefore, the above-mentioned VT ratio is a value obtained by dividing the primary voltage by the secondary voltage, and is therefore 6600 V / 110 V = 60. Further, since the primary current of the current transformer 16 (CT) uses 20A, 50A, 100A, 150A, and 200A as the receiving current, the CT ratio is a value obtained by dividing the primary current by the secondary current. Therefore, 4, 10, 20, 30, and 40 are obtained. As a result, as shown in the table of FIG. 5, the transformation ratio (VT ratio × CT ratio) is 240, 600, 1200, 1800, 2400.

  In the calibration mode of the demand pulse output device 13, a pulse constant corresponding to the type of the watt hour meter 11 can be selected as shown in FIG. By selecting this pulse constant, the metering pulse in the demand pulse output device 13 can be matched with the metering pulse output from the watt hour meter 11, and the demand monitoring device 12 connected to the demand pulse output device 13 is connected to the watt hour meter 11. It is possible to operate in the same manner as when connected to. In this calibration mode, for example, one of the pulse constants of 50000 pulses / kWh and 2000 pulses / kWh is selected. When a pulse constant of 50,000 pulses / kWh is selected, the demand pulse output device 13 sends the measurement pulse [= (measured power / transformation ratio) × 50000 pulses / kWh] to the demand monitoring device 12 according to the output instruction. .

  Here, when the metamorphic ratio is 240 (VT ratio 60 × CT ratio 4), the demand pulse output device 13 sets the output to 240 kW and continues for 1 hour, and then the measurement pulse corresponding to 240 kW / 240 = 1 kWh. (50000 pulses) is output to the demand monitoring device 12. In the demand monitoring device 12 to which the measurement pulse (50000 pulses) is inputted, the amount of electric power becomes 120 kWh by calculation of 30 minutes of measurement pulse (25000 pulses) × transformation ratio (240) / pulse constant (50000 pulses / kWh). The average power 240 kW (= 120 kWh / 0.5 h) is displayed. As described above, since the demand monitoring device 12 displays 240 kW with respect to the output 240 kW of the demand pulse output device 13, the transformation ratio of the demand pulse output device 13 and the transformation ratio of the demand monitoring device 12 (watt-hour meter 11). Must be set the same.

  In the variable mode of the demand pulse output device 13, as shown in FIG. 3, the pulse constant corresponding to the type of the watt hour meter 11 can be selected by a button operation, and the power when the demand monitoring device 12 issues an alarm The amount can be changed by a button operation, and the timed pulse can be set to a reset state by a button operation. Thereby, the measurement pulse in the demand pulse output device 13 can be matched with the measurement pulse output from the watt hour meter 11, and the demand monitoring device 12 to which the demand pulse output device 13 is connected is connected to the watt hour meter 11. It can be operated in the same way. In addition, the amount of power when the demand monitoring device 12 issues an alarm can be set to an arbitrary value. In this case, the timed pulse for measuring the electric energy is reset. That is, in response to the output instruction, the demand pulse output device 13 sends the reset timed pulse (interval of 30 minutes) to the demand monitoring device 12.

  Here, regarding the point that the pulse constant according to the type of the watt hour meter 11 can be selected, as in the case of the calibration mode described above, when a pulse constant of 50000 pulses / kWh is selected, a measurement pulse is generated by an output instruction. The demand pulse output device 13 sends [= (measured power / transformation ratio) × 50000 pulses / kWh) to the demand monitoring device 12. In addition, regarding the point that the amount of electric power at the time of issuing an alarm can be changed by the demand monitoring device 12, for example, when changing the amount of electric power at the time of issuing an alarm from 20 kWh to 50 kWh, the measurement pulse is increased by 2.5 times. What is necessary is just to change the magnification of the weighing pulse. That is, in response to the output instruction, the demand pulse output device 13 sends 2.5 times the measurement pulse [= (measured power / transformation ratio) × 50000 pulses / kWh) to the demand monitoring device 12.

  In the display mode of the demand pulse output device 13, as shown in FIG. 4, by automatically increasing or decreasing the measurement pulse output from the demand pulse output device 13, the alarm state “margin” “ A series of operations for outputting “attention” and “limit” in a stepwise manner from the demand monitoring device 12 to the display device 14 and from the display device 14 to the demand pulse output device 13 is performed, for example, about 20 for each increased / decreased measurement pulse. It can be repeated in about minutes. Thereby, it can be confirmed whether the display operation and control operation of the demand monitoring apparatus 12 are normally repeated. The display device 14 includes a display unit that displays the alarm states “margin”, “caution”, and “limit” by lighting the lamp.

  As for the display mode, as shown in the table of FIG. 6, the case where the transformation ratio is 240 (see the table of FIG. 5) will be described in detail. In this case, in the demand monitoring device 12, as shown in FIG. 7, the warning threshold value for shifting the alarm state from “margin” to “caution” is set in advance to, for example, 65 kWh, and from “caution” to “limit”. The limit threshold value to be transferred is set in advance to 75 kWh, for example. In this display mode, a series of operations including the following (1) to (5) are repeated.

  (1) First, a measurement pulse corresponding to the command value “96 kW” as “margin output” in the table of FIG. 6 is generated by the demand pulse output device 13 and sent to the demand monitoring device 12. The demand monitoring device 12 integrates and measures the measurement pulse from the demand pulse output device 13 and displays the measurement value while increasing the measurement value to the command value “96 kW”. When the integrated weighing value based on the command value “96 kW” becomes larger than the caution threshold value 65 kW set by the demand monitoring device 12, the demand monitoring device 12 sends a “caution” signal to the display device 14. Upon receiving the “caution” signal from the demand monitoring device 12, the display device 14 displays the alarm state “caution” by lighting the lamp and sends the “caution” signal to the demand pulse output device 13.

  (2) When the demand pulse output device 13 receives the “caution” signal from the display device 14, the command value “96 kW” is reduced to the command value “80 kW” as “caution output”, and the command value “ A measurement pulse corresponding to “80 kW” is generated and sent to the demand monitoring device 12. The demand monitoring device 12 integrates and measures the measurement pulse from the demand pulse output device 13 and displays the measurement value while increasing the measurement value to the command value “80 kW”. When the integrated measurement value based on the command value “80 kW” becomes larger than the limit threshold value 75 kW set by the demand monitoring device 12, the demand monitoring device 12 sends a “limit” signal to the display device 14. When receiving the “limit” signal from the demand monitoring device 12, the display device 14 displays the alarm state “limit” by lighting the lamp and sends the “limit” signal to the demand pulse output device 13.

  (3) When the demand pulse output device 13 receives the “limit” signal from the display device 14, the command value “80 kW” is reduced to the command value “60 kW” as the “limit output”, and the command value “ A measurement pulse corresponding to “60 kW” is generated and sent to the demand monitoring device 12. The demand monitoring device 12 integrates and measures the measurement pulse from the demand pulse output device 13 and displays the measurement value while reducing the measurement value to the command value “60 kW”. When the integrated weighing value based on the command value “60 kW” becomes smaller than the caution threshold value 65 kW set by the demand monitoring device 12, the demand monitoring device 12 cancels the alarm state “limit” and displays the “caution” signal. 14 to send. Upon receiving the “caution” signal from the demand monitoring device 12, the display device 14 displays the alarm state “caution” by lighting the lamp and sends the “caution” signal to the demand pulse output device 13.

  (4) In this case, the demand pulse output device 13 receives the “caution” signal from the display device 14, but monitors the measurement pulse in a state where the measurement pulse corresponding to the aforementioned command value “60 kW” is maintained. Send to device 12. The demand monitoring device 12 integrates and measures the measurement pulse from the demand pulse output device 13 and displays the measurement value while reducing the measurement value to the command value “60 kW”. When the integrated weighing value based on the command value “60 kW” becomes smaller than the caution threshold value 65 kW set by the demand monitoring device 12, the demand monitoring device 12 cancels the alarm state “caution” and displays the “margin” signal. 14 to send. Upon receiving the “margin” signal from the demand monitoring device 12, the display device 14 displays the alarm state “margin” by lighting the lamp and sends the “margin” signal to the demand pulse output device 13.

  (5) When the demand pulse output device 13 receives the “margin” signal from the display device 14 and the integrated weighing value based on the command value “60 kW” reaches 60 kW, the command value “60 kW” is output as the “margin output”. Is increased to a command value “96 kW”, and a measurement pulse corresponding to the command value “96 kW” is generated and sent to the demand monitoring device 12. In this way, by repeating the operations (1) to (4) described above, the demand monitoring device 12 automatically repeats the alarm states “margin”, “caution”, and “limit”. It can be confirmed whether the display operation and the control operation are normally repeated.

Next, as shown in FIG. 8, the operation check mode of the demand pulse output device 13 is as follows when the above-mentioned attention threshold value 65 kW is set as the target demand power and the limit threshold value 75 kW is set as the limit demand power. 18 operation confirmations are made possible. In FIG. 8, the demand period T is 30 minutes, and the demand period T is divided into the _first period T ₁ (0 to 10 minutes), the middle period T ₂ (10 to 20 minutes), and the latter period T ₃ (20 to 30 minutes). , 5 min sampling time Δt year on T ₁ for integrating meter the amount of power demand monitor 12, 3 minutes metaphase T _2, illustrates the case of setting in the late T ₃ to 1 minute. The division period of the _first period T ₁ , the middle period T ₂ and the _second period T ₃ of the demand cycle T and the sampling time Δt in the _first period T ₁ , the middle period T ₂ and the _second period T ₃ are not limited to those described above and are arbitrary. .

In the operation check mode, to reach any point (midpoint t) in metaphase T ₂ of the demand period T, metering pulses corresponding to the above limitations demand power, for example 80kW corresponding increased thereby metering pulse demand pulse output to The demand monitoring device 12 detects the slope (ΔP / Δt) of the increase in power at the intermediate point t in the middle period T ₂ of the demand cycle T. The demand monitoring device 12 measures the predicted demand power corresponding to the slope of the increase in power, and gradually shifts from the alarm state “margin” to the alarm state “limit” via the alarm state “caution”. Based on the demand power, the load device 18 connected to the output of the demand monitoring device 12 is controlled to be equal to or less than the target demand power at the end of the demand cycle T, and from the alarm state “limit” to the alarm state “caution”. Transition to the alarm state “margin” step by step.

  By controlling the load device 18 in this way, the demand monitoring device 12 shifts from the alarm state “margin” to the alarm state “limit” via the alarm state “caution”, so that the output of the demand monitoring device 12 The load device 18 shifts from 100% operation to 70% operation to 0% operation (stop), and the demand monitoring device 12 shifts from the alarm state “limit” to the alarm state “caution” to the alarm state “margin”. As a result, it is confirmed whether or not the load device 18 shifts from 0% operation (stop) to 70% operation and then to 100% operation by the output of the demand monitoring device 12. In this way, it is possible to confirm whether or not the load device 18 is normally controlled so as to be equal to or lower than the target demand power at the end of the demand cycle T. In this operation confirmation mode, the operation can be confirmed by directly measuring the load power (or load current) before the control of the load device 18 and the load power (or load current) after the control.

  In the operation check mode of the demand pulse output device 13, the operation of the load device 18 connected to the output of the demand monitoring device 12 based on an alarm state corresponding to an arbitrary measurement pulse output from the demand pulse output device 13. Confirmation is also possible. For example, when a measurement pulse corresponding to the command value “60 kW” is generated by the demand pulse output device 13 and sent to the demand monitoring device 12, the demand monitoring device 12 becomes “margin” and the output is loaded equipment. It is confirmed whether 18 operates 100%. Further, when a measurement pulse corresponding to the command value “70 kW” is generated by the demand pulse output device 13 and sent to the demand monitoring device 12, the demand monitoring device 12 becomes a “caution” state, and the output is a load device. Confirms whether or not 70% will operate. Further, when a measuring pulse corresponding to the command value “96 kW” is generated by the demand pulse output device 13 and sent to the demand monitoring device 12, the demand monitoring device 12 becomes a “limit” state, and the load device It is confirmed whether or not 18 operates (stops) 0%. Accordingly, it is possible to check whether the load device is normally controlled by following an alarm state corresponding to an arbitrary measurement pulse. In this operation confirmation mode, it is not always necessary to connect the display device 14 to the demand monitoring device 12 and the demand pulse output device 13. Also in this operation confirmation mode, the operation can be confirmed by directly measuring the load power (or load current) before control of the load device 18 and the load power (or load current) after control.

  In this demand monitoring system, the demand monitoring device 12 measures the demand value (kW) and the integrated weighing value (kWh) corresponding to the pseudo weighing pulse output from the demand pulse output device 13, and the demand value (kW) and A memory 19 for recording the integrated measurement value (kWh) is built in the demand monitoring device 12. Thereby, it is possible to confirm whether or not the demand monitoring device 12 accurately measures the demand value (kW) and the integrated weighing value (kWh) corresponding to the pseudo weighing pulse. The data recorded in this memory, that is, the date, demand value (kW), and integrated metric value (kWh) can be taken out from the demand monitoring device 12 by wire or wirelessly.

  In this demand monitoring system, a structure in which the demand pulse output device 13 and the demand monitoring device 12 are integrated is possible. Thus, by integrating the demand pulse output device 13 and the demand monitoring device 12, the demand monitoring system can be made compact. In the operating state of the demand monitoring device 12 connected to the watt hour meter 11, the demand pulse output device 13 is not connected to the demand monitoring device 12, and the test at the time of installing the demand monitoring device 12 or the inspection after the installation is performed. When implementing, it is necessary to connect the demand pulse output device 13 to the demand monitoring device 12. Therefore, when the demand pulse output device 13 and the demand monitoring device 12 are integrated, the demand monitoring device 12 and the demand pulse output device 13 may be connected or disconnected by either hardware or software.

  In the above embodiment, the case where the watt hour meter 11 outputs both the timed pulse and the metering pulse has been described. However, the present invention is not limited to this, and the case where the watt hour meter 11 outputs only the metering pulse. It is also applicable to.

  The present invention is not limited to the above-described embodiments, and can of course be implemented in various forms without departing from the gist of the present invention. It includes the equivalent meanings recited in the claims and the equivalents recited in the claims, and all modifications within the scope.

11 Electricity meter 12 Demand monitoring device 13 Demand pulse output device 14 Display device

Claims (10)

This is a demand monitoring system that performs a test at the time of installation or an inspection after installation for a demand monitoring device that constantly monitors the maximum power demand based on the measurement pulse output from a watt hour meter installed in a power consumer receiving high voltage power. And
Connected to the demand monitoring device removed from the watt-hour meter, generates a quasi-measurement pulse equivalent to the metric pulse output from the watt-hour meter, and sends the pseudo-measurement pulse to the demand monitoring device A demand pulse output device, and a display device that is connected to the demand monitoring device and connected to the demand pulse output device and displays an alarm state according to demand power, and is output from the demand pulse output device. A demand monitoring system characterized in that the weighing pulse is variable .   The watt hour meter outputs a timed pulse in addition to the metering pulse, and the demand pulse output device artificially generates a metering pulse and a timed pulse equivalent to the metering pulse and the timed pulse output from the power meter. The demand monitoring system according to claim 1, wherein the pseudo measurement pulse and the timed pulse are transmitted to the demand monitoring device.   The demand monitoring system according to claim 1 or 2, wherein the demand pulse output device can select a menu mode, a calibration mode, a variable mode, a display mode, and an operation check mode.   The demand monitoring system according to any one of claims 1 to 3, wherein in the menu mode of the demand pulse output device, a transformation ratio can be set so as to output a metering pulse corresponding to a type of the watt-hour meter.   The demand monitoring system according to any one of claims 1 to 3, wherein the calibration mode of the demand pulse output device can select a pulse constant according to a type of the watt-hour meter.   The variable mode of the demand pulse output device makes it possible to select a pulse constant according to the type of the watt-hour meter and to change the amount of power when an alarm is issued in the demand monitoring device. The demand monitoring system according to any one of the above.   In the display mode of the demand pulse output device, by automatically changing the measurement pulse output from the demand pulse output device, an alarm state corresponding to the measurement pulse is output from the demand monitoring device to the display device. The demand monitoring system according to any one of claims 1 to 3, wherein a series of operations output from the display device to the demand pulse output device can be repeated for each variable measurement pulse.   In the operation check mode of the demand pulse output device, a measurement pulse corresponding to a limit demand power or more is output from the demand pulse output device, a slope of an increase in power is detected by a demand monitoring device at an intermediate point of the demand cycle, The demand demand power corresponding to the inclination of the power increase is measured by the demand monitoring device, and based on the predicted demand power, the load device connected to the output of the demand monitoring device is equal to or less than the target demand power at the end point of the demand cycle. The demand monitoring system according to any one of claims 1 to 3, wherein control is performed so that   A demand value corresponding to a pseudo measurement pulse output from the demand pulse output device and an integrated measurement value are measured by the demand monitoring device, and a memory for recording the demand value and the integrated measurement value is incorporated in the demand monitoring device. The demand monitoring system according to any one of claims 1 to 8.   The demand monitoring system according to any one of claims 1 to 9, wherein the demand pulse output device and the demand monitoring device are integrated.

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