JP6016605B2 - Electronic instrument - Google Patents

Description

  The present invention relates to an electronic instrument whose output is used, for example, for monitoring the amount of electricity such as voltage, current, power, etc. of circuits in factories, buildings, and other load systems.

  The electronic meter includes a measurement unit that generates measurement data that is a measured electric quantity of the electric circuit from a current of the electric circuit detected by the current sensor and a voltage of the electric circuit detected by the voltage sensor, a data storage unit, and A data processing unit is provided that periodically reads out the measurement data from the measurement unit and stores read measurement data, which is measurement data that has been read out, in the data storage unit.

  Although it is not an electronic instrument, in a data collection device used for vehicles, etc., even if the amount of data collected exceeds the capacity of the storage device, data collection will not occur with as much timing as possible. There has been proposed a data collection device that enables the above. (See Patent Document 1)

JP 2012-52918 A

  As described above, a measurement unit that generates measurement data, which is a measured electric quantity of the electric circuit, from a current of the electric circuit detected by the current sensor and a voltage of the electric circuit detected by the voltage sensor, a data storage unit, and In an electronic instrument including a data processing unit that periodically reads out the measurement data from the measurement unit and stores the read measurement data, which is the measurement data that has been read out, in the data storage unit, for example, the voltage of an electric circuit When monitoring the above, since there is no change under normal circumstances, voltage measurement data is stored at long intervals (for example, every 5 minutes). However, if the voltage drops temporarily due to the effects of lightning strikes on the electric circuit, etc., or if the voltage drops due to insufficient supply by power companies such as overseas, there may be an instantaneous drop of about 100 ms. There is a request to memorize detailed data such as every 10ms. Since it is not known when the voltage drop occurs in such a case, a large amount of memory is required, and it is not realistic to mount a large amount of memory in an electronic instrument that is a measuring device.

  Also, for example, when monitoring the leakage current of the electric circuit, since there is no change, current measurement data is stored at long intervals (for example, every 5 minutes). However, there is a demand for storing detailed data such as every 100 ms, because when a leakage occurs due to a device failure or water leakage, it may occur for about 1 second. Even in such a case, since it is not known when the electric leakage occurs, a large amount of memory is required, and it is not realistic to mount a large amount of memory in an electronic instrument.

  In addition, for example, when monitoring the current of the electric circuit, the current data is stored at a long interval (for example, every 5 minutes). However, there is a request to store detailed data such as every 100 ms when the starting current is confirmed when the device is moved or when an abnormal current occurs due to device abnormality. Even in such a case, since it is not known when the starting current and the abnormal current are generated, a large amount of memory is required, and it is not realistic to mount a large amount of memory in the electronic instrument.

  The present invention has been made in view of such a situation, and an object thereof is to enable an electronic instrument to store detailed measurement data that requires a large-capacity data storage unit. is there.

A measurement unit that generates measurement data, which is a measured electric quantity of the electric circuit, from a current of the electric circuit detected by the current sensor and a voltage of the electric circuit detected by the voltage sensor, a threshold setting unit that sets a threshold, and data storage A data processing unit that periodically reads the measurement data from the measurement unit, compares the read measurement data with the threshold value, and stores the measurement data in the data storage unit, and A data output unit for transmitting the measurement data stored in the data storage unit to the outside of the instrument, and the data processing unit distributes the measurement data for one period of the periodic reading to each of the plurality of blocks. stored in the data storage area of the block, the result of the comparison with the threshold value, the threshold measurement data stored across a said plurality of blocks super If the measured data is not included, the measured data stored in the subsequent blocks other than the first part of the plurality of blocks in which the measured data is stored is deleted. Then, the subsequent plurality of blocks including the block from which the measurement data has been deleted by distributing the measurement data that has been read out for the next period to a plurality of subsequent blocks including the block from which the measurement data has been deleted The data is stored in the data storage area of each of the blocks.

The present invention relates to a measurement unit that generates measurement data, which is a measured electric quantity of the electric circuit, from a current of the electric circuit detected by a current sensor and a voltage of the electric circuit detected by a voltage sensor, and a threshold setting that sets a threshold value Data that periodically reads the measurement data from the measurement unit, the data storage unit, and the measurement unit, compares the measurement data that has been read with the threshold value, and stores the measurement data in the data storage unit A processing unit, and a data output unit for transmitting the measurement data stored in the data storage unit to the outside of the instrument, wherein the data processing unit stores the measurement data for one period of the periodic reading into the plurality of blocks. dispersed and stored in the data storage area of each of said blocks, a result of comparison with the threshold value, the measurement data stored across a said plurality of blocks When the measurement data exceeding the threshold is not included, the measurement data is stored in a subsequent block other than the first partial block among the plurality of blocks in which the measurement data is stored. Delete the measurement data, distribute the measurement data read out for the next period to a plurality of subsequent blocks including the block from which the measurement data has been deleted, and delete the block from which the measurement data has been deleted. Since it is stored in the data storage area of each of a plurality of subsequent blocks including it, there is an effect that detailed measurement data can be stored in an electronic instrument that requires a large-capacity data storage unit.

It is a figure which shows Embodiment 1 of this invention, and is a connection diagram which shows the example of the use electric circuit of an electronic meter. It is a figure which shows Embodiment 1 of this invention, and is a figure which shows the example of the change of the voltage at the time of the lightning strike to an electric circuit. It is a figure which shows Embodiment 1 of this invention, and is a figure which shows the example of the change of an electric current when electric leakage generate | occur | produces in an electric circuit. It is a figure which shows Embodiment 1 of this invention, and is a figure which shows the example of the change of the starting current of the apparatus using electric motors, such as a machine tool. It is a figure which shows Embodiment 1 of this invention, and is a block diagram which shows the example of the internal structure of an electronic type meter. It is a figure which shows Embodiment 1 of this invention, and is operation | movement explanatory drawing which shows the example about the measurement data process in the electronic type meter illustrated in FIG. 5 with a flowchart. FIG. 7 is a diagram illustrating the first embodiment of the present invention, and is an operation explanatory diagram illustrating an example of a data storage control operation to a data storage unit in the electronic instrument illustrated in FIG. 5 in a flowchart. In the figure which shows Embodiment 1 of this invention, in the data storage part, the measurement data storage state when there exists measurement data exceeding a threshold value in a certain cycle 1 and the next cycle 3 next to the cycle 1 (Example 1) FIG. It is a figure which shows Embodiment 1 of this invention, and is a figure which illustrates the measurement data storage state when the data storage part does not have the data exceeding a threshold value (example 2). It is a figure which shows Embodiment 1 of this invention, and is operation | movement explanatory drawing which illustrates the example which reads and processes continuous data from the measurement data stored in the data storage part. It is a figure which shows Embodiment 1 of this invention, and is operation | movement explanatory drawing which illustrates the example which reads and processes thinning-out data from the measurement data stored in the data storage part with a flowchart. FIG. 5 is a diagram showing the first embodiment of the present invention, where (1) is an example 1 (when the data storage section includes measurement data exceeding a threshold value in a certain cycle 1 and the next cycle 3 after the cycle 1). (2) is a figure which shows the concept in the case of taking out thinning data in the situation of Example 1, respectively. In the figure which shows Embodiment 1 of this invention, (1) is the concept in the case of taking out continuous data in the situation of Example 2 (when there is no data exceeding a threshold value in a data storage part), (2) is Example 2. It is a figure which shows the concept in the case of taking out thinning data in the situation of each. It is a figure which shows Embodiment 1 of this invention, and is a figure which shows the example which stored the actual measurement data corresponding to FIG. 2 (The figure which shows the example of the change of the voltage at the time of the lightning strike to an electric circuit) in a data storage part. . It is a figure which shows Embodiment 1 of this invention, and is a figure which shows the example which stored the actual measurement data corresponding to FIG. 3 (the figure which shows the example of the change of the electric current when electric leakage has generate | occur | produced) in the data storage part. is there. In the figure which shows Embodiment 1 of this invention, the example which stored the actual measurement data corresponding to FIG. 4 (The figure which shows the example of the change of the starting current of the apparatus using electric motors, such as a machine tool) in a data storage part is shown. FIG.

Embodiment 1 FIG.
Embodiment 1 of the present invention will be described below with reference to FIGS.

  In FIG. 1, loads L1 to Ln of a plurality of machine tools or the like are fed from a power receiving point RP through an electric circuit FL that is stepped down via a power receiving transformer Tr22 and a feeder transformer Tr6, and as illustrated, a plurality of loads L1 to Ln. Each voltage and current is detected by the voltage sensor VT and current sensor CT, and the electronic instruments 1a to 1n corresponding to each load input the outputs of the corresponding voltage sensor VT and current sensor CT for monitoring, etc. Measurement data of a necessary amount of electricity (for example, each effective value of voltage, current, and power) is generated, and the measurement data is stored.

  In the electric circuit FL illustrated in FIG. 1, the generation time is not known, but the voltage drop due to the lightning strike illustrated in FIG. 2, the generation of leakage current illustrated in FIG. 3, the machine tool illustrated in FIG. Accompanied by the generation of a starting current for the load. Hereinafter, FIGS. 2 to 4 will be described in detail.

In FIG. 2, when the voltage is monitored, since there is no change under normal circumstances, data is stored at long intervals (for example, every 5 minutes).
However, if the voltage drops temporarily due to the effects of lightning, etc., or if the voltage drops due to a shortage of supply from overseas or other power companies, there may be a momentary drop of about 100 ms. There is a request to store data.
The reason for this requirement is to confirm whether the effect of the instantaneous drop such as a semiconductor device has an effect on the product.
Since it is not known when a lightning strike will occur on the electric circuit FL, a large amount of memory is required in the data storage section of the electronic instrument, and it is not realistic to install a large amount of memory in the electronic instrument, which is a measuring instrument. Normally, it was necessary to send data every 10ms to the host system at all times and save the data on a personal computer with a large memory.
In the present embodiment, for example, data every 5 minutes is stored, and if it falls below the threshold, data before and after the occurrence is stored every 10 ms, so that an electronic instrument that does not require a large-capacity memory can be obtained. It is possible to provide.

In FIG. 3, when monitoring leakage current, there is no change, so data is stored at long intervals (for example, every 5 minutes).
However, there is a demand for storing detailed data such as every 100 ms, because when a leakage occurs due to a device failure or water leakage, it may occur for about 1 second.
This is to identify the time that has occurred and to help identify the cause of the leakage current.
Since it is not known when the leakage current will occur, a large amount of memory is required in the data storage part of the electronic meter, and it is not realistic to install it in the measuring device. It was necessary to save the data on a computer with a large amount of memory.
In this embodiment, for example, data every 5 minutes is stored, and if the threshold value is exceeded, data before and after the occurrence is stored every 100 ms, so that an instrument that does not require a large-capacity memory is stored. It is possible to provide.

In FIG. 4, even when current is monitored, data is stored at long intervals (for example, every 5 minutes).
However, there is a demand to store detailed data such as every 100 ms when the starting current is confirmed when the device is moved or when a device abnormality occurs.
This means that when the device starts up, a starting current of 2 to 3 seconds, or several tens of seconds depending on the device is generated.
Since it is not known when the starting current is generated, a large amount of memory is required, and it is not realistic to install it in measurement equipment. Normally, data is sent every 100 ms to the host system at all times, and a large capacity memory There was a need to save data on a computer.
In this embodiment, data is stored every 5 minutes, and if the threshold is exceeded, the data before and after the occurrence is stored every 100 ms, so that an electronic instrument that does not require a large-capacity memory Can be provided.

  Hereinafter, an example of an electronic instrument that does not require a large-capacity memory will be described with reference to FIGS. An example of the internal configuration of the electronic meter is as illustrated in FIG. 5, and the electronic meter 1 includes a measuring unit 11, a control device 12, a setting unit 13, and an output unit 14.

  The measurement unit 11 samples the current and voltage signals output from the current sensor CT and voltage sensor VT, calculates the effective values of current, voltage, and power, for example, every 100 msec, and stores the calculation results in the RAM 111 as measurement data. .

The control device 12 includes a data processing unit 121, a data storage unit (memory) 122, a thinned data reading processing unit 123, and a continuous data reading processing unit 124. The functions of each unit will be clarified in the operation description to be described later. .
The setting unit 13 includes a threshold value setting unit 131, and a data sampling setting unit 132 having a sampling interval setting function 1321 and a thinning data interval setting function 1322, and the functions of each unit will be clarified in the operation description to be described later. .

The operation will be described below.
FIG. 6 is a flowchart illustrating an example of measurement data processing in the electronic instrument illustrated in FIG. 5. In FIG. 6, the measurement unit 11 samples the current and voltage signals output from the current sensor CT and the voltage sensor VT. The effective values of current, voltage, and power are calculated as sampling data every 100 msec, and the calculation results are stored in the RAM 111 as measurement data (step ST61).

Measurement data, which is sampling data stored in the RAM 111, is periodically read out (ie, sampled) at a set cycle by the data processing unit 121, and the measurement data read by this sampling and the threshold setting unit 131 set The threshold value is compared with the data processing unit 121 (step ST62), and as a result of the comparison in step ST62, there is measurement data that exceeds the threshold value (YES) in the measurement data that is sampling data (step ST63) Then, the threshold excess flag is written in the threshold excess information of the threshold determination unit in the data processing unit 121 (step ST64), and the process proceeds to the next data storage control step (step ST65).
As a result of the comparison in step ST62, if there is no measurement data that exceeds the threshold in the measurement data that is sampling data (NO) (step ST63), the process proceeds to the data storage control step (step ST65).
Data storage control (step ST65) means control for storing measurement data, which is sampling data, in the data storage unit (memory) 122 by the data processing unit 121. The detailed contents thereof will be described later with reference to FIG.

  The data processing unit 121 determines whether or not the measurement (collection of measurement data from the RAM 111) of one cycle for sampling and reading the measurement data stored in the RAM 111 has been completed (step ST66). If the measurement for the period has been completed (if YES), it is determined whether or not the threshold excess information has a threshold excess flag in step ST64 (step ST67). As a result of the determination in step ST67, the threshold excess information is obtained. If there is a threshold excess flag in step ST64 (YES), threshold excess information is set in the headers of all blocks in the corresponding cycle (step ST610). The result of setting the threshold excess information in the headers of all the blocks in the corresponding cycle is illustrated in FIG.

  When threshold excess information is set in the headers of all the blocks in the corresponding cycle in step ST610, the threshold excess information is cleared in the threshold excess information in the threshold determination unit in step ST64 (step ST611).

  As a result of the determination in step ST67, if the threshold value excess information does not include the threshold value excess flag in step ST64 (NO), data of blocks other than block 1 in the corresponding cycle is deleted (step ST68), and then block 1 in the corresponding cycle No threshold exceeded is set in the header (step ST69). FIG. 8 shows the result of deleting data of blocks other than block 1 in the corresponding cycle and setting “no threshold exceeded” in the header of block 1 in the corresponding cycle.

In FIG. 6, the definition of the period, sampling data, and the number of blocks is as follows. Cycle: period in which detailed data is to be kept, sampling data: effective value calculated by the measurement unit 11, number of blocks: interval of thinned data / sampling interval.
Further, if period = T, sampling interval = Δt, and thinned data interval = ΔT, the number of data in one cycle (M) = T / Δt, the number of data in one block (n) = T / ΔT, the number of blocks (N ) = M / n.
In addition, the thinned data is measured data stored in each data storage area of each block in FIG. 8, FIG. 9, FIG. This means storage sampling 1-2, sampling 1-4, etc., whereas continuous data means sampling 1-1, sampling 1-2, sampling 1-3,... Sampling 1-n, sampling 3 −1, sampling 3-2, sampling 3-3,... Sampling 3-n, etc. means data rearranged in the order of sampling.

Next, data storage control in the data storage unit 122 by the data processing unit 121 will be described with reference to FIG.
The data processing unit 121 determines whether the sampling data (measurement data) read from the RAM 111 of the measurement unit 11 is measurement data with a new cycle (step ST71), and if the result of the determination is measurement data with a new cycle (YES) Secures a memory area for the number of blocks (N) calculated from the thinned data interval ΔT and the sampling interval Δt as a new cycle in the data storage unit 122 (step ST72).

  Next, a block number is assigned to N blocks (data storage areas grouped for each of a plurality of data storage areas in the memory area of the data storage unit 122) by dividing an area for one period in the reserved memory area into N pieces. 1 to N are added (step ST73).

After the processing of step ST73, the sampling data is stored in the first data area (data storage area) of block 1 (step ST74 ).

If the result of determination in step ST71 is not measurement data of a new cycle (NO), it is determined whether the previously stored block number is N (1) (step ST75), and the determination result is that the previously stored block number is If N (1) (YES), the sampling data (measurement data) read by the data processing unit 121 from the RAM 111 of the measurement unit 11 is stored in the block 1 (step ST76).
If the number of the block stored last time is not N (1) (if NO), the sampling data (measurement data) is stored in the next block stored last time (step ST77).

  6 and 7, for example, when there is measurement data exceeding the threshold in period 1 and period 3 (example 1), the data storage unit (memory ) In the data storage area of 122, it is secured by being divided into two blocks of block 1 and block 2 in period 1, and thinned data (measurement data) is stored in each data storage area in block 1 as shown in FIG. Sampling data (measurement data) 1-1 (abbreviated as “sampling 1-1” in the figure. Similarly abbreviated below), sampling 1-3, sampling 1-5,... Sampling 1- (n -1) is stored, and sampling data 1-2, sampling 1-4, sampling 1-6,... Sampling 1-n, which are thinned data (measurement data), are stored in each data storage area in block 2 In addition, 8 all the blocks (Block 1, Block 2) of the period 1 as shown in (2) in the header of the threshold excess information is set as "threshold exceeded".

FIGS. 8 (3) and 4 (4) are examples in which the measurement data in cycle 2 are stored in the same manner. In cycle 2 there is no measurement data exceeding the threshold value, so as shown in FIG. 8 (4), the first block 1 is left without being deleted, blocks other than the first block 1 (block 2) are deleted, and the header of the first block 1 left without being deleted has a threshold value exceeding the threshold in the measurement data of period 2. Information “no threshold exceeded” indicating that there is no data is set.
Here, since the block (block 2) other than the first block 1 is deleted, the capacity of the data storage unit (memory) can be increased accordingly.

    FIG. 8 (5) shows that the first block 1 of the next cycle 3 is secured in the area where the block (block 2) other than the first block 1 in the cycle 2 is deleted, and the thinned-out data of the cycle 3 ( Measurement data) Sampling 3-1, Sampling 3-3, Sampling 3-5, ... Sampling 3- (n-1) is stored, and the first block 1 of cycle 3 is cycled to block 2 of cycle 3 that follows. 3 thinning data (measurement data) sampling 3-2, sampling 3-4, sampling 3-6,... Sampling 3-n are stored. Since there is data exceeding the threshold in the measurement data of period 3, the information “exceeding threshold” exceeding the threshold is set in the header of all locks (block 1, block 2) of period 3.

As illustrated in FIG. 8, in FIG. 8 (1), the data is measured by the measuring unit 11 for data having a certain period, and the data sorting function in the data processing unit 121 is used. ), The measurement data storage area in the data storage unit (memory) is divided into a plurality of blocks (two blocks in the illustrated example), and the sampling data (measurement data) is stored. is there.
In FIG. 8 (2), all the data measured within this cycle are determined by the threshold value determination unit, and when there is data exceeding the threshold value, each data storage unit in the data processing unit 121 uses the data organizing function. A state in which information exceeding the threshold is set in the header information of the block is illustrated.

In FIG. 8 (3), the same sampling as in FIG. 8 (1) is performed for the next period.
In FIG. 8 (4), all data measured within this cycle are determined by the threshold value determination function in the data processing unit 121. If there is no data exceeding the threshold value, the data organization function in the data processing unit 121 is used. Then, a block that can be ignored as an electronic instrument (block 2 with period 2 in the figure) is deleted from the data storage unit 122, and information indicating that the threshold is not exceeded is included in the header information of other blocks (block 1 with period 2 in the figure) The state in which is set is illustrated.

In FIG. 8 (5), the same sampling as in FIG. 8 (1) is performed for the next period.
In FIG. 8 (6), all data measured within this cycle are determined by the threshold determination function in the data processing unit 121, and if there is data exceeding the threshold, the data organizing function in the data processing unit 121 is used. In this example, a state in which threshold excess information is set in the header information of each block of the data storage unit 122 is illustrated.

  9 (1) to 9 (6) show the case where there is no data exceeding the threshold (example 2), and the measurement data stored in the data storage unit 122 is the same as that shown in FIGS. 8 (1) to 8 (6). 6 is a diagram illustrating a storage process and a storage result in a data storage unit 122. FIG. 9 (1) to (6) will be understood from the above-described operation description, the description of FIGS. 8 (1) to (6), and the contents shown in FIGS. 9 (1) to (6). Omit.

  The case where the measurement data stored in the data storage unit (memory) 122 as described above is output to the outside of the electronic instrument in response to a request from the outside of the electronic instrument will be described with reference to FIGS. .

  FIG. 10 illustrates the case where the continuous data reading process is performed in response to a request from the outside of the electronic instrument. In FIG. 10, whether or not there is a request for reading continuous data in the control device 12. Judgment is made (step ST101), and if the result of the determination is that there is a request to read continuous data (YES), the continuous data read processing unit 124 determines whether there is threshold excess information in the header information (step ST102), As a result of the determination, if there is threshold excess information in the header information (YES), data of all cycles with threshold excess information is organized in the sampling order by the output organization function in the continuous data read processing unit 124 (step ST103).

In step ST103, when the data of all the periods having the threshold excess information are arranged in the sampling order, the arranged data is then output by the data output unit 14 (step ST104).
As a result of the determination in step ST102, when there is no threshold excess information in the header information (in the case of NO), none of the data of all cycles with threshold excess information is output from the data output unit 14 (step ST105).

FIG. 11 exemplifies a case where the thinned data reading process is performed in response to a request from the outside of the electronic instrument. In FIG. 11, whether or not there is a request for reading thinned data in the control device 12. Judgment is made (step ST111), and if there is a request to read the thinned data (YES), the thinned data read processing unit 123 determines whether the header information includes threshold excess information (step ST112). As a result of the determination, when there is threshold excess information in the header information (YES), the data of the block 1 of all the cycles is output in order. (Step ST113).
If the result of determination in step ST112 is that there is no threshold excess information in the header information (in the case of NO), the data excluding the header information is output from the output unit 14 as it is. (Step ST114).

  FIG. 13 (1) shows the concept of taking out continuous data in the situation of Example 2 (when there is no data exceeding the threshold in the data storage unit), and FIG. 13 (2) shows the case of taking out thinned data in the situation of Example 2. It is a figure which shows the concept of each.

As illustrated in FIG. 13 (1), when there is a request for retrieving continuous data from the outside in the situation of Example 2 (when there is no data exceeding the threshold in the data storage unit), the data of the control device 12 is externally transmitted. When there is a continuous data read request in a read acceptance unit (not shown), the output data determination function of the control device 12 confirms that the header information in the data storage unit 122 does not exceed the threshold.
In this example, since there is no data exceeding the threshold, output from the output unit 14 is not performed.

As illustrated in FIG. 13 (2), when there is an external request for extracting thinned data in the situation of Example 2 (when there is no data exceeding the threshold in the data storage unit), the data of the control device 12 is externally transmitted. When there is a thinning data read request in the read receiving unit (not shown), the output data determination function of the control device 12 confirms that the header information in the data storage unit does not exceed the threshold value.
Since there is no data exceeding the threshold, the output data organizing unit edits the data excluding the header information as shown in FIG.

Next, FIG. 14 which shows the example which stored the actual measurement data corresponding to FIG. 2 (The figure which shows the example of the change of the voltage at the time of the lightning strike to an electric circuit) in a data storage part is demonstrated.
FIG. 14 shows the conditions of sampling data (V): voltage (effective value), period (T): 5 minutes, sampling interval (Δt): 10 milliseconds, and thinned data interval (ΔT): 10 seconds, And conditions depending on these conditions (number of data in one cycle (M): 5 minutes / 10 milliseconds = 30,000), number of data in one block (n): 5 minutes / 10 seconds = 30, number of blocks (N) : 30000/30 = 1000) If there is no measurement data exceeding the threshold in all blocks, all other blocks (block 2 to block 1000) other than block 1 are deleted, so 30000 measurements Data is reduced to 30 pieces. Therefore, a large margin can be made in the data storage unit (memory) 122, and it can be seen that the effect of the present embodiment is great.

Next, FIG. 15 showing an example in which actual measurement data corresponding to FIG. 3 (a diagram showing an example of a change in current when leakage occurs in an electric circuit) is stored in the data storage unit will be described.
FIG. 15 shows the conditions of sampling data (A): leakage current (effective value), period (T): 5 minutes, sampling interval (Δt): 100 milliseconds, and thinned data interval (ΔT): 1 second. , And conditions depending on these conditions (number of data in one cycle (M): 5 minutes / 100 milliseconds = 3000, number of data in one block (n): 5 minutes / 10 seconds = 30, number of blocks (N ): 3000/30 = 100) If there is no measurement data exceeding the threshold in all blocks, all other blocks (block 2 to block 100) other than block 1 are deleted, so 3000 blocks Measurement data is reduced to 30 pieces. Therefore, a large margin can be made in the data storage unit (memory) 122, and it can be seen that the effect of the present embodiment is great.

Next, FIG. 16 showing an example in which actual measurement data corresponding to FIG. 4 (a diagram showing an example of a change in starting current of an apparatus using an electric motor such as a machine tool) is stored in the data storage unit will be described.
FIG. 16 shows the conditions of sampling data (A): starting current (effective value), period (T): 5 minutes, sampling interval (Δt): 100 milliseconds, and thinned data interval (ΔT): 1 second. , And conditions depending on these conditions (number of data in one cycle (M): 5 minutes / 100 milliseconds = 3000, number of data in one block (n): 5 minutes / 10 seconds = 30, number of blocks (N ): 3000/30 = 100) If there is no measurement data exceeding the threshold in all blocks, all other blocks (block 2 to block 100) other than block 1 are deleted, so 3000 blocks Measurement data is reduced to 30 pieces. Therefore, a large margin can be made in the data storage unit (memory) 122, and it can be seen that the effect of the present embodiment is great.

As described above, the first embodiment has the following technical features.
Feature 1: a measurement unit that generates measurement data that is a measured electric quantity of the electric circuit from an electric current detected by a current sensor and a voltage of the electric circuit detected by a voltage sensor, a data storage unit, and the measurement unit A data processing unit that periodically reads out the measurement data from the data storage unit that stores the read measurement data in the data storage unit, and a data output that transmits the measurement data stored in the data storage unit to the outside of the instrument The data storage unit is divided into a plurality of blocks having a predetermined number of data storage areas, and the data processing unit is configured to transfer the measurement data for one period of the periodic reading into the plurality of blocks. Measurement that is distributed and stored in the data storage area of each block, and the measurement data that is distributed and stored in the plurality of blocks exceeds a threshold value Data is not included, the measurement data stored in the subsequent blocks other than the first part of the plurality of blocks in which the measurement data is stored is deleted, and this data is deleted. A plurality of subsequent blocks including blocks from which the measurement data has been deleted by distributing the measurement data read out for the next period to a plurality of subsequent blocks including the block from which the measurement data has been deleted It is an electronic instrument stored in each said data storage area.
Feature 2: In the electronic instrument according to Feature 1, the data processing unit includes data exceeding a threshold value in the measurement data distributed in the plurality of blocks and stored in the data storage area If the measurement data is stored, the measurement data stored in the subsequent blocks other than the first partial block of the plurality of blocks in which the measurement data is stored is left without being deleted. The measurement data read out for the next one period is distributed to a plurality of blocks following the plurality of blocks in which the read-out measurement data for the period is stored in a distributed manner. To store.
Feature 3: In the electronic instrument according to Feature 2, the data processing unit includes data exceeding a threshold value in measurement data distributed in the plurality of blocks and stored in the data storage area If there is, the threshold excess information indicating that the measurement data exceeding the threshold exists in the header area of the block including the measurement data exceeding the threshold is set.
Feature 4: a measurement unit that calculates an electrical quantity (effective value) from current and voltage signals, a data storage unit that is divided into a predetermined number N of areas and stores the electrical quantity, and the electrical quantity from the measurement unit An electronic instrument comprising: a data processing unit that reads and stores data in order in a predetermined number N of the storage unit; and a data read processing unit that reads measurement data from the data storage unit and transmits the data to the outside In the above, when the measurement data in one cycle does not exceed the threshold when the measurement for one cycle is completed, the data processing unit deletes the data of the area after the second block of the cycle and An area with the next cycle is secured in the area, and when the measurement data within the cycle exceeds the threshold, a new area with the next cycle is secured.
Feature 5: In the electronic instrument according to Feature 4, when the measurement data in the cycle exceeds the threshold value, the data processing unit sets the threshold value excess information in the header information of the area.

In the present invention, the embodiments can be modified as appropriate within the scope of the invention.
In addition, in each figure, the same code | symbol shows the same or an equivalent part.

  1 Electronic instrument, 11 measuring unit, 111 RAM, 12 control unit, 121 data processing unit, 122 data storage unit (memory), 123 thinned data reading processing unit, 124 continuous data reading processing unit, 13 setting unit, 131 threshold setting Section, 132 data sampling setting section, 1321 sampling interval setting function, 1322 thinning data interval setting function, 14 output section.

Claims (3)

A measurement unit that generates measurement data that is a measured electric quantity of the electric circuit by calculation from the electric current of the electric circuit detected by the current sensor and the voltage of the electric circuit detected by the voltage sensor;
A threshold setting unit for setting a threshold;
Data storage,
A data processing unit that periodically reads the measurement data from the measurement unit, compares the read measurement data with the threshold value, and stores the measurement data in the data storage unit, and the data It has a data output unit that transmits measurement data stored in the storage unit to the outside of the instrument,
The data storage unit is divided into a plurality of blocks having a predetermined number of data storage areas,
Wherein the data processing unit stores distributed measurement data for one period of the periodic read to the plurality of blocks in the data storage area of each of the blocks, the comparison of the threshold value results, the plurality If the measurement data distributed and stored in the block does not include measurement data that exceeds the threshold, the first partial block of the plurality of blocks in which the measurement data is stored The measurement data stored in other subsequent blocks other than is deleted, and the measurement data that has been read out for the next cycle is transferred to a plurality of subsequent blocks including the block from which the measurement data has been deleted. An electronic instrument characterized in that it is stored in the data storage area of each of a plurality of subsequent blocks including a block from which the measurement data is deleted in a distributed manner. 2. The electronic instrument according to claim 1, wherein as a result of comparison with the threshold value, measurement data distributed in the plurality of blocks and stored in the data storage area includes data exceeding the threshold value. The data processing unit does not delete the measurement data stored in a subsequent block other than the first partial block of the plurality of blocks in which the measurement data is stored. The measurement data that has been read out for one cycle is read out for the next cycle in a plurality of blocks that follow the plurality of blocks that are stored in a distributed manner. An electronic instrument characterized by storing measurement data in a distributed manner. 3. The electronic instrument according to claim 2, wherein as a result of comparison with the threshold value, measurement data distributed in the plurality of blocks and stored in the data storage area includes data exceeding the threshold value. If so , the data processing unit sets over-threshold information which means that there is measurement data that exceeds the threshold in the header area of the block that includes the measurement data that exceeds the threshold An electronic instrument characterized by