JP3338594B2 - Integrated current dynamometer - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an integrated current dynamometer for measuring integrated power and integrated current of direct current power and alternating current power, and more particularly, to an integrated current dynamometer having a sensor connected to a main body of the integrated current dynamometer via a connector. It relates to the integrated current dynamometer that is used.

[0002]

2. Description of the Related Art In recent years, electric vehicles have been developed at a rapid pace. For this reason, at present, a verification driving test for measuring a driving distance or the like that can be performed by one charge of the prototype electric vehicle is also actively performed. In such a confirmation driving test, it is necessary to measure the integrated power of the DC power charged and discharged to and from the battery mounted on the electric vehicle for the following reasons. That is, the travelable distance when traveling on a flat road can be theoretically calculated from the capacity of the battery. However, in an electric vehicle, when traveling down a hill, the battery can be charged. For this reason, it is necessary to measure the battery performance more practically by traveling on various traveling roads such as a flat road and a slope road.

In such a measurement, an integrating wattmeter having a clamp-type sensor may be used. This integrating wattmeter includes a wattmeter main body and a clamp-type sensor connected to the wattmeter main body by a connector via a cable. In this conventional integrating wattmeter, a wattmeter main body is placed in a vehicle, and a cable connecting a battery and a motor is clamped by a clamp-type sensor, whereby DC power charged and discharged to and from the battery is measured.

[0004]

However, the conventional integrating wattmeter has the following problems. That is, when the connector for connecting the clamp-type sensor and the wattmeter main body is not securely connected, the connector may be disconnected while traveling on a rough road. In such a case, if the measurement is continued, there is a problem that an accurate measurement result cannot be obtained, and the confirmation running test performed over a long time may be neglected. In this case, there is also an integrated wattmeter that determines that an abnormal state has occurred when a sensor signal of the clamp-type sensor is not input, and automatically performs a reset process. However, such an integrated wattmeter has the same problem in that the integrated power already measured is cleared by the reset process, so that the time taken for the measurement is wasted.

[0005] The present invention has been made in view of the above problems, and has as its main object to provide an integrated current dynamometer capable of reliably integrating and measuring the power and current of a measurement object.

[0006]

According to a first aspect of the present invention, there is provided an integrated current dynamometer for outputting a sensor signal obtained by measuring at least one of a current and a voltage via a sensor-side connector. A dynamometer main body that has a main body side connector for connecting a sensor side connector and measures an integrated current force based on the sensor signal input through the main body side connector; and wherein the sensor side connector is connected to the main body side.
Connector disconnection detection that detects disconnection from connector
Means and said connector disconnection detecting means
In integrated current power meter side connector disengagement is provided with warning means <br/> and to alert when it is detected, the connector away
When the detachment is detected by the detachment detection means, the product
Measurement control means for stopping the measurement of the calculated current force;
When the measurement is stopped by the control means,
Storage means for storing the integrated current force based on the
The connector disengagement detecting means is provided on the main body side connector.
Further detecting the connection of the sensor-side connector to the
The measurement control means is operated by the connector disconnection detection means.
When the connection of the sensor-side connector is detected,
Together to resume the constant, the integrated current power based on the measurement
The integration process for integrating the stored integrated current force is executed.
Characterized in that row.

In this integrated current dynamometer, when the sensor-side connector is detached from the main-unit-side connector, the connector detachment detecting means detects the detachment. Next, the alarm means gives an alarm to the effect that the user has left by visual means or auditory means.
Thus, the measurer can know that the sensor-side connector has been disconnected, and can immediately restart the measurement by connecting the sensor-side connector. Also,
In this integrated ammeter, the connector disconnection detection means
When disconnection of the sensor-side connector is detected, the measurement control means
Stops the measurement of the integrated current force, and the storage means stores the measurement.
The integrated current force, which is a fixed result, is stored. Then the connector
The connection of the sensor-side connector is detected by the
Measurement control means restarts the measurement and
Calculation, that is, the integrated current force in the restarted measurement,
The integrated current force measured before the sensor connector is disconnected
A process of integrating and continuing the measurement is executed. this
Measurement due to the disconnection of the sensor-side connector.
A constant error is included in the integrated power or malfunctions
There is no. Also, the sensor side connector is connected by the measurer.
The integrated current force can be measured immediately.
it can.

[0008] The integrated current dynamometer according to the second aspect is the first aspect of the invention.
The integrated current dynamometer according to the above, further comprising an integrating switch means for outputting an integrated signal at the time of operation, the measurement control means,
When the connection of the sensor-side connector is detected by the connector detachment detecting means and an integration signal is output, the integration processing is executed.

In this integrated current dynamometer, when the connection of the sensor-side connector is detected and the integration switch means is operated, the integrated current force of the restarted measurement is not measured until the sensor-side connector is disconnected. Is integrated with the measured integrated current force. As a result, the measurer's will decides whether or not to add to the integrated current force measured before the sensor-side connector is disconnected. Will be taken into account.

According to a third aspect of the present invention, there is provided an integrated current dynamometer according to the first aspect.
Or the integrated current dynamometer according to 2, wherein the current dynamometer main body is configured to be connectable to a plurality of types of sensors, and includes sensor identification means for identifying the types.
The connector detachment detecting means detects the attachment / detachment of the sensor-side connector based on the identification result of the sensor identifying means.

In this integrated current dynamometer, the sensor identification means can automatically perform measurement according to the connected sensor, and the main structure of the connector disconnection detection means can also be used as the sensor identification means. Therefore, the connector detachment detecting means can be configured substantially inexpensively. In this case, the cost of the connector detachment detecting means can be extremely reduced by configuring other components of the connector detaching means by software.

According to a fourth aspect of the present invention, there is provided an integrated current dynamometer according to the first aspect.
3. The integrated current dynamometer according to any one of items 1 to 3 , further comprising a power supply and power failure detection means for detecting power supply and power failure, wherein the measurement control means stores the integrated current force during measurement when the power failure is detected. And the measurement is stopped, and when the power supply is detected, the measurement is restarted and the integration process is executed.

In this integrated current dynamometer, the storage means generally used as a measure against a power failure and the storage means for storing the integrated current force when the sensor-side connector is disconnected can be used. As a result, the cost of the storage means can be substantially reduced.

[0014]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing an embodiment of an integrated current dynamometer according to the present invention;

FIG. 1 is a block diagram of an integrated wattmeter (integrated current dynamometer) 1. As shown in FIG. 1, the integrating wattmeter 1 includes a wattmeter main body (integrated current dynamometer main body) 2 and a sensor main body (sensor) 3. A connector (body-side connector) 4 is attached to the case of the wattmeter body 2, and a connector (sensor-side connector) 5 connected to the sensor body 3 via a cable (not shown) is attached to the connector 4. Connectable.

As shown in FIG.
It includes a U11, an A / D converter 12, an I / O unit 13, a display unit (alarm unit) 14, and a switch unit 15. These units are connected to each other by a bus line 16.

The CPU 11 constitutes the measurement control means, the connector detachment detection means, the sensor identification means, and the power failure detection means in the present invention. The CPU 11 controls the measurement of the integrated power, detects the attachment / detachment of the connector 5, and detects the connection. Various processes including a process of identifying the sensor body 3 are performed. Also,
The CPU 11 has therein a RAM (storage means) 11a for storing the value of the measured integrated power and a battery 1
7 is backed up. As a result, the contents stored in the RAM 11a are not erased due to a power failure or the like.

The A / D converter 12 converts an analog current signal output from the sensor body 3 into a digital signal. The I / O unit 13 outputs a type identification signal for identifying the type of the sensor body 3 connected via the connectors 4 and 5 to the CPU 11. The type identification signal is a 3-bit parallel signal, and is configured so that the signal voltage of each bit becomes a voltage corresponding to the voltage of each of the identification signals 1 to 3 applied to the terminals e to g. In this case, since the terminals e to g are pulled up by the resistors 18 to 20, respectively, when the connector 5 is not connected to the connector 4, the I / O unit 13 outputs the “111” signal, which is all high level. When the connector 5 is connected, any one of the terminals e to g is connected to the ground via the sensor main body 3 so that the bit corresponding to the terminal connected to the ground has a low-level type. Output an identification signal. The display unit 14 displays the measured integrated power, an error when an abnormal state occurs, and the like. The switch unit 15 is a restart switch for restarting the measurement when the connector 5 is detached from the connector 4 and then reconnected, and integrates the newly measured integrated power with the integrated power measured before the connector 5 was disconnected. It is provided with an integrating switch (integrating switch means) that is operated when performing measurement by means of a switch, and various switches for setting a measuring range and the like.

The sensor body 3 detects a current value of DC power or AC power, and includes a clamp sensor 21 and a sensor circuit 22. The clamp sensor 21
Although not particularly limited, it is configured as a flux gate type, and by clamping the conductor, the magnetic detection element outputs a voltage value according to a magnetic flux density generated in the magnetic core based on a current flowing through the conductor as a current signal. I do. The sensor circuit 22 amplifies the current signal output from the clamp sensor 21 and outputs the amplified signal to the terminal a of the connector 5.

The sensor body 3 is divided into a plurality of types according to the measurable current value, and "1" to "7" for each type.
Are set in advance. Identification numbers has become settable by connecting any one or more of the terminals e~g of the connector 5 being weighted respectively 2 ^{0-2 2} to ground. Specifically, the terminal e
And g are connected to ground, the identification number is set to "5". For this reason, a printed pattern for connecting the terminals e to g of the connector 5 to the ground is wired on the printed circuit board in the sensor body 3. The sensor main body 3 shown in the figure has a detection rated current of 20 A, and its identification number is set to "1" by connecting the terminal e of the connector 5 to the ground by the printed pattern 23.

Next, an outline of the overall operation of the integrating wattmeter 1 will be described. When the connector 5 is connected to the connector 4, the power meter main body 2 is connected to the sensor main body 3 via the terminal c.
Is supplied with power. In this state, for example, the CPU 11 monitors the type identification signal from the I / O unit 13 every 200 mS to perform a connector attachment / detachment detection process for determining whether or not the connector 5 is connected.
An identification process for identifying the type of the connected sensor body 3 is performed. Specifically, in the connector attachment / detachment detection process, when the type identification signal is “111”, the CPU 11 determines that the connector 5 has been disconnected, and executes a measurement restart process described later. On the other hand, when the type identification signal is other than “111”, the CPU 11 determines that the connector 5 is connected, identifies the type of the sensor body 3, and operates any switch of the switch unit 15. When the measurement is performed, the measurement range is switched to a measurement range according to the type of the sensor body 3.

Further, the CPU 11 operates the terminal a of the connector 4.
The integrated power is measured by multiplying the current value of the current signal input through the multiplying unit by the voltage value of the measurement target detected by the voltage detection means (not shown). Then, the measurement result is stored in a storage area of a predetermined address of the RAM 11a. On the other hand, when the power supply is stopped due to disconnection of a power cable or the like or a power failure, the CPU 11 determines that the power supply has been stopped.
It is stored in M11a. When the power supply is restarted and the restart switch of the switch unit 15 is operated, the CPU 11 restarts the measurement of the integrated power,
The newly measured integrated power is added to the integrated power stored in the RAM 11a. This prevents the measured integrated power from being cleared by stopping power supply.

Next, the connector attachment / detachment detection processing and the measurement restart processing by the CPU 11 will be described more specifically with reference to FIG.

When a measurement start switch (not shown) of the switch section 15 is operated, the CPU 11 starts measuring integrated power (step 31). Next, the CPU 11
In the connector attachment / detachment detection processing, it is monitored whether or not the connector 5 has been disconnected (step 32). When it is determined that the user has left, the CPU 11 executes a measurement restart process described below. In this process, the CPU 11 stops the measurement, stores the measurement result so far in the RAM 11a, and displays an error indicating that the connector 5 has been disconnected on the display unit 14 (step 33). In this case, the CPU 11
Causes a printing device (not shown) to print the fact that the connector 5 has been disconnected and the measurement time from the start of measurement. Then C
The PU 11 monitors whether the connector 5 is connected (Step 34). If it is determined that the connection has been established,
U11 performs an identification process, and determines whether or not the type is the same as that of the original sensor main body 3 based on the type identification signal (step 35). If the same type is determined, the CPU
In step 11, after the error display is canceled without changing the measurement range, the measurement is started based on the newly input current signal, and the measurement result is displayed on the display unit 14 (step 36). In parallel with this, the CPU 11 monitors whether or not the accumulation switch has been operated (step 37), and when it is determined that the accumulation switch has been operated, executes the following accumulation processing. That is, the CPU 11 determines in step 33 that RA
The integrated power obtained by adding the newly measured integrated power to the integrated power stored in M11a is set as a new integrated power.
While rewriting the stored contents of 1a, the display unit 14 displays the new integrated power. Thereafter, the CPU 11 continuously measures the integrated power, rewrites the stored contents of the RAM 11a, displays the integrated power on the display unit 14 (step 37), and at the same time, executes the connector attachment / detachment detection processing every 200 mS. (Step 32).

On the other hand, in step 35 described above, if it is determined that the sensor main body 3 is of another type,
11 causes the display unit 14 to blink information (for example, the detected rated current value) on the type of the sensor main body 3 (step 41). Next, it is monitored whether or not the connector 5 has been detached (step 42). When it is determined that the connector 5 has been detached, it is determined that the user has replaced the sensor body 3 and
The CPU 11 returns to step 33, displays an error on the display unit 14 (step 33), and executes the steps after step 34. In step 42, the connector 5 does not come off during the predetermined time and the switch 15
Is operated, the CPU 11 determines that the measurement range is changed by the user's will.
Is set to the measurement range according to the type of the sensor body 3,
The integrated power stored in the RAM 11a is cleared, and a new integrated power measurement is started (step 4).
3), this process ends.

As described above, in the integrating wattmeter according to the present embodiment, when the connector 5 is disconnected, an error is displayed on the display unit 14, so that the measurer can immediately know that fact. As a result, by connecting the connector 5, the measurement of the integrated power can be restarted. As a result, the measurement result already measured is not lost.

In this embodiment, the integrated wattmeter has been described. However, the present invention can also be applied to an integrated ammeter, and in such a case, the same effect can be obtained by the same processing.

In this embodiment, an example has been described in which an error is displayed on the display unit 14 as an alarm means. However, the present invention is not limited to this, and an alarm sound may be generated by a speaker or the like. Furthermore, the case where the alarm is performed when the connector 5 is accidentally disconnected has been described. However, the present invention is not limited to this, and the alarm can be applied to a case where the measurer replaces another type of connector 5 by his / her own will.

Further, regarding the type of the sensor body 3,
The present invention is not limited to the type shown in the present embodiment, and it is needless to say that the present invention can be applied to a device using a Hall element or a sensor for voltage measurement detached. Also, the procedure of the processing content can be appropriately changed.

[0030]

As described above, according to the integrated current dynamometer according to the present invention, even when the connector on the sensor side is disconnected, an alarm is issued by the alarm means, so that the power to be measured can be reliably integrated and measured. it can. When the detachment of the connector on the sensor side is detected, the measurement control means stops the measurement, and the storage means stores the integrated current as the measurement result.
Remember the power. After that, the connector disconnection detection means
When the connection of the sensor-side connector is detected, the measurement control means
There, along with the to resume the measurement, the integration process, in other words resumption of
The integrated current force in the measured measurement is
Measurement is continued by integrating the integrated current force measured before
Let Thereby, the measurement error caused by the detachment of the sensor side connector is not included in the integrated current force,
Accurate measurements can be made. Further, by using the main structure of the connector detachment detecting means also as the sensor identifying means, the connector detachment detecting means can be constituted at low cost. Similarly, by also using the storage unit for storing the data of the integrated current force at the time of the power failure, the manufacturing cost of the storage unit can be substantially reduced.

[Brief description of the drawings]

FIG. 1 is a block diagram of an integrating wattmeter according to an embodiment of the present invention.

FIG. 2 is a flowchart illustrating processes such as a connector attachment / detachment detection process and a measurement restart process in the integrating wattmeter according to the embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Integrated wattmeter 2 Wattmeter main body 3 Sensor main body 4 Connector 5 Connector 11 CPU 14 Display part 15 Switch part

Continuation of front page (56) References JP-A-5-41256 (JP, A) JP-A-5-53672 (JP, A) JP-A-60-207076 (JP, A) JP-A-6-273459 (JP) , A) Japanese Utility Model 1988-17469 (JP, U) Japanese Utility Model Application Hei 2-121460 (JP, U) (58) Fields investigated (Int. Cl. ⁷ , DB name) G01R 11/00-11/66 G01R 21/00-22/00 130

Claims (4)

(57) [Claims] 1. A sensor for outputting a sensor signal obtained by measuring at least one of a current and a voltage via a sensor-side connector, and a main-body-side connector for connecting the sensor-side connector. And a sensor for measuring the integrated current force based on the sensor signal, and the sensor-side connector is separated from the body-side connector.
Connector disconnection detection means for detecting disconnection,
Disconnection of the sensor-side connector by
And an alarm means for alarming when disconnection is detected , wherein the disconnection is detected by the connector disconnection detection means.
Measurement control means for stopping the measurement of the integrated current force when
And the measurement is stopped by the measurement control means.
Storage means for storing the integrated current force based on the measurement
Further comprising:
Further connecting the sensor-side connector to the body-side connector.
The measurement control means detects the disconnection of the connector.
When the connection of the sensor side connector is detected by the step
At the same time, the measurement is restarted and based on the measurement.
Integrating the integrated current force into the stored integrated current force
An integrating current dynamometer that performs an integrating process . 2. The apparatus according to claim 1, further comprising: an integration switch for outputting an integration signal at the time of operation, wherein said measurement control means detects a connection of said sensor-side connector by said connector disconnection detection means and outputs said integration signal. , the integrated current power meter of claim 1, wherein performing said integration processing. 3. The current dynamometer main body is configured to be connectable to a plurality of types of the sensors, and includes a sensor identification unit for identifying the types, and the connector detachment detection unit includes the sensor identification unit. 3. The integrated current dynamometer according to claim 1, wherein the connection / disconnection of the sensor-side connector is detected based on the identification result of the means. 4. A power supply and power failure detecting means for detecting a power supply and a power failure, wherein the measurement control section stores the integrated current force during measurement in the storage means when the power failure is detected, and The integrated current dynamometer according to any one of claims 1 to 3 , wherein the measurement is stopped, and when the power supply is detected, the measurement is restarted and the integration process is executed.