JPH06331427A - Electronic balance - Google Patents

Abstract

PURPOSE:To provide an inexpensive electronic balance unnecessary for setting working of a troublesome correction time. CONSTITUTION:An electronic balance has a correction weight (a), a load detection means (b), an addition and subtraction means (c), an automatic correction means (d), a correction stop means (e), a use state detection means (f) and a correction time modification means (g). The load detection means (b) detects the weight of a loaded object to be measured in a normal state. The addition and subtraction means (c) loads the weight (a) on the load detection means (b) and subtracts the weight (a) from a loaded state. The automatic correction means (d) transmits a control signal to the addition and subtraction means (c) when it is a correction time and specified correction operation is performed. The correction stop means (e) transmits a correction operation stop signal to the automatic correction means (d) when a correction stop condition is satisfied and automatic correction operation is stopped. The use state detection means (f) detects an initial use start time after correction operation is performed. The correction time modification means (g) calculates an interval of a correction time to the initial use start time in an hour and/or day unit and the correction time is shifted in response to the size of the interval.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic scale, and more particularly to an improved technique of an electronic scale having a function of automatically performing a calibration operation at a preset calibration time.

[0002]

2. Description of the Related Art In weighing devices such as electronic scales, measurement sensitivity changes due to changes in environmental conditions such as temperature and humidity, which causes fluctuations in measurement errors, which hinders high-precision measurement. Need to avoid. Therefore, in this kind of high-accuracy weighing device, there is provided a device in which a calibration means for calibrating the sensitivity is built in the device.

In a weighing apparatus having such a built-in calibration means, for example, as disclosed in Japanese Utility Model Laid-Open No. 3-30831, a calibration weight whose accurate mass is known and this calibration weight are weighed. The device has an adding / removing means for loading or removing, and from the calibration load value when the calibration weight is placed on the weighing device by the adding / removing means, it is judged whether or not an accurate measurement value can be obtained. Alternatively, the calibration is updated.

By the way, in this type of high-accuracy weighing apparatus, it is most desirable to perform the calibration operation immediately before using the apparatus. However, the start-up time of the weighing device is not necessarily performed at a fixed time, and it is very difficult to predict the start-up time uniquely, and it is practically almost impossible. Therefore, conventionally, for example, as disclosed in the above publication, a time to be calibrated is set in advance, and when the calibrated time comes, a means for regularly and automatically calibrating, As shown in Japanese Patent Application No. 4-83144, the usage status of the weighing device is sampled, its operation pattern is extracted and stored, and an appropriate calibration time is decided based on this operation pattern. Means to do so have been proposed. However, such a conventional weighing device has the technical problems described below.

[0005]

That is, in the former configuration, for example, in a department such as an inspection department of a production line where the weighing device is used almost every day at a certain time, it is an effective means, but in the research and development department, etc. As such, it is not always an effective means in a non-routine work department. Also, in the former configuration, it is necessary to set the calibration time, but when setting this calibration time, the built-in clock must be adjusted to the local time, and it is also necessary to set multiple calibrations on the production line. When using the weighing device of No. 2, the calibration time must be reset every time such a situation occurs due to a change in production shift, a change in installation location, etc. The task of setting the calibration time was very troublesome.

On the other hand, the latter configuration does not require a troublesome calibration time setting and is effective in a non-routine work department, but requires a considerable amount of memory capacity to extract the operation pattern. Therefore, there is a problem that the cost of the device increases. The present invention has been made in view of such conventional problems, and an object thereof is to provide an inexpensive electronic scale that does not require troublesome calibration time setting work. It is in.

[0007]

In order to achieve the above object, the present invention provides a built-in calibration weight, a load detection means, and an addition / removal means for loading or removing the calibration weight on the load detection means. In an electronic scale for measuring the weight of a measuring object loaded on the load detecting means, which comprises an automatic calibrating means for sending a control signal to the adding and removing means to perform a calibration operation at a preset calibration time, Based on the use state detecting means for detecting the use start time of the electronic scale and the detection value of the use state detecting means, the interval from the calibration time to the use start time is calculated in units of hours and / or days, and this interval is calculated. And a calibration time correction means for shifting the calibration time back and forth according to the size of the calibration time.

[0008] The electronic scale, during use of the scale, power supply voltage,
When calibration stop conditions such as sudden changes in environmental conditions are met,
Calibration stop means for sending a calibration operation stop signal can be provided to the automatic calibration means.

[0009]

According to the electronic scale having the above-mentioned structure, the built-in calibration weight, the load detecting means, the adding and removing means for loading or removing the calibration weight on the load detecting means, and the adding and removing at the preset calibration time. Since the automatic calibration means for sending the control signal to the means to perform the calibration operation is provided, first, basically, the calibration operation is automatically performed at the set calibration time.

At this time, the calibration according to claim 2 is arranged to send a calibration operation stop signal to the automatic calibration means when the calibration stop condition such as the use of the balance, the sudden change of the power supply voltage or the environmental condition is satisfied. When the stop means is provided, if the calibration operation is inconvenient, the calibration operation is stopped even at the calibration time. Also, based on the use state detection means for detecting the start of use of the electronic scale and the detection value of the use state detection means, the interval from the calibration time to the start of use is calculated in hours and / or days, and this interval It has a calibration time adjustment means to shift the calibration time back and forth according to the size, so the calibration time should be changed according to the usage situation of the electronic scale, and the calibration operation should be performed immediately before it is used as much as possible. You can

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT A preferred embodiment of the present invention will be described in detail below with reference to the accompanying drawings. 1 to 5 show an embodiment of an electronic scale according to the present invention. As shown in the functional block diagram of FIG. 1, the electronic balance shown in FIG. 1 has a calibration weight a, a load detection means b, an addition / removal means c, an automatic calibration means d, a calibration stop means e, and State detection means f
And calibration time correction means g.

The mass for calibration a, whose mass is accurately determined in advance, is built in the electronic balance main body h. In the steady state, the load detecting means b detects the weight of the measured object to be loaded and is built in the electronic scale main body h. The adding / removing means c loads the calibration weight a on the load detecting means b, or removes the calibration weight a from this loaded state.

The automatic calibration means d receives the output signal of the clock i, and when the calibration time T ₀ preset by the calibration time setting means j comes, it sends a control signal to the adding / removing means c,
Perform a predetermined calibration operation. The calibration stop means g receives the output signal of the environment sensor k and the output signal of the usage state detection means f, and the calibration stop condition such as when the balance is in use, environmental conditions or a sudden change in power supply voltage is detected. When satisfied,
A calibration operation stop signal is sent to the automatic calibration means d, and the automatic calibration operation is stopped even at the calibration time T ₀ .

The use state detecting means f receives the output signal of the load detecting means b and detects the first start time of use after the calibration operation is performed by the automatic calibrating means d. The calibration time correction means g calculates the interval from the calibration time T ₀ to the start of the first use in units of hours and / or days based on the detection value of the usage state detection means f, and corresponds to the magnitude of this interval. , The calibration time T ₀ is shifted back and forth.

FIG. 2 shows a more specific structural example of the electronic scale of the present invention. The electronic scale shown in the figure is roughly configured by an electronic scale main body unit 10, a weight addition / removal mechanism 12, and a control unit 14. The electronic scale body 10 is provided with a tray 10a on which the object to be measured is placed and loaded, and a load detector 10b which operates in conjunction with the tray 10a.
A calibration weight 16 is built therein.

Further, the main body portion 10 is provided with an environment sensor 18 for detecting temperature and humidity. Weight control mechanism 1
Reference numeral 2 is a known mechanism including a cam, a link mechanism, a drive motor, and the like. Based on a control signal sent from the control unit 14, the calibration weight 16 is placed on the tray 10a and loaded, Alternatively, it has a function of removing the weight 16 from the dish portion 10a from this loaded state.

In this embodiment, the control unit 14 is mainly composed of a so-called microcomputer, and has a CPU.
14a, memory (R0M14b, RAM14c, non-volatile RAM14d), input / output interface (I / F)
14e, display 14f, printer 14g, keyboard 1
4h, a clock 14i, and an analog-digital (A / D) converter 14j.

The load detection unit 10b and the output side of the environment sensor 18 are connected to the analog-digital converter 14j, and the measurement value detected by the load detection unit 10b and the detection value of the environment sensor 18 are connected to the control unit 14. Entered in. ROM1
4b includes a normal measurement program and the use /
A non-use determination program and a calibration time adjustment program are stored in advance.

In the RAM 14c, a data area is set in which the measured values of the load detector 10b fetched via the A / D converter 14j are sequentially written. Non-volatile R
An area for storing the calibration time T _{0 and the} like is set in the AM 14d. The display 14f sequentially digitally displays the weight of the measurement object detected by the load detection unit 10b. The printer 14g sequentially digitally prints the weight of the measurement object detected by the load detection unit 10b. The calibration time T ₀ is input from the keyboard 14h, or a command for manual calibration is input.

The normal measurement program executed by the control unit 14 is a known program, and the description thereof is omitted.
The specific program executed by the electronic scale of the present invention shown in FIG. 5 will be described. In the following description, the preset calibration time T ₀ will be described as being already input, for example, when the scale is shipped from the factory.

The procedure shown in FIG. 3 is for use / non-use determination. When the procedure starts, first, in step s1, the output of the load detector 10b is the A / D converter 14.
It is taken in through j, and it is judged whether or not the load value is in the vicinity of 0, and when it is judged that the load value is not in the vicinity of 0, it means that the scale is used. In step s2, the flag in use is set and the procedure ends.

On the other hand, if it is determined in step s1 that the load value is near 0, step s3 is executed.
In step s3, it is determined whether or not the load value of the load detection unit 10b has a variation equal to or greater than a predetermined limit value. If the variation is greater than or equal to the predetermined limit value, the measurement target is placed on the dish 10a. Immediately after, or the measuring object is placed on the dish 10a.
Since it is considered that the scale has just been removed, the scale is judged to be in use in this case, the flag in use is set in step s2, and the procedure ends.

When it is determined in step s3 that the variation of the load value is not more than the limit value, step s4 is executed. In step s4, the keyboard 1 within the past T minutes
It is determined whether or not there is an operation for 4 h, and if the keyboard 14 h is operated within T minutes, it is determined that the scale is in use, and in step s2, the in-use flag is set and the procedure proceeds. finish.

If it is determined in step s4 that the keyboard 14h has not been operated within the past T minutes, step s5 is executed. In step s5, it is determined whether or not a command has been received within the past T minutes. If a command has been received within T minutes, some signal is sent from the control unit 14, so the scale is in use. Then, the flag is set in use in step s2, and the procedure ends.

On the other hand, if it is determined in step s5 that no command has been received within the past T minutes, it means that the scale is in a non-use state. Ends. 4 and 5 show an example of the calibration time adjustment program. The program shown in FIG. 4 shows a case where the calibration time T ₀ is shifted forward. When the procedure shown in the figure is started, it is first determined in step s10 whether or not the calibration time T ₀ is reached by the clock 14i.
When the CPU 14a receives the output signal of, and the calibration time T ₀ is reached, the process proceeds to step s11. In step s11, it is determined whether or not the scale is used. The judgment standard executed in step s11 is as shown in FIG.
It is performed based on the procedure shown in.

When it is determined in step s11 that the scale is in use, a predetermined holding time T is set in step s12.
It is determined whether or not the use is continued even after (for example, about one hour) has elapsed. The reason for providing such steps is that the scale is used, but its use is irregular, and if the use state is released in a relatively short time, the next calibration time should be corrected. This is because it is not performed, and when the usage state is released before the time T has elapsed in step s12, the procedure ends.

If it is determined in step s12 that the usage state continues even after the time T has passed,
In step s13, 1 (hour) is subtracted from the calibration time T ₀ , a new calibration time T ₁ is set, and the procedure ends.
On the other hand, if it is determined in step s11 that the scale is not in use, step s14 is executed. Step s1
In 4, the output of the environment sensor 18 is taken in via the A / D converter 14j, and it is determined whether or not the output is stable. At this time, the judgment criterion is, for example, calculation of the output fluctuation of the sensor 18 within a predetermined time.

If it is determined that the output is not stable, the reliability cannot be ensured even if automatic calibration is performed, so the procedure is terminated. Sensor 18 in step s14
If it is determined that the output is stable, it is determined in step s15 that the power source is stable. The reason for providing this step is that the calibration is stopped because the load value is not stable within a certain time after the power is turned on. In other words, the power supply voltage is normally stabilized by the stabilization circuit and supplied to each part, so it is only necessary to calibrate within a fixed time immediately after the power is turned on.
If it is determined that the power supply is not stable, reliability cannot be ensured even if automatic calibration is performed, so the procedure ends.

If it is determined in step s15 that the power source is stable, a control signal is sent to the weight adding / removing mechanism 12 in step s16 to perform automatic calibration operation.
When this operation ends, the procedure also ends. Although this automatic calibration operation is a known one, it will be briefly described. The weight 16 is placed on the pan 10a by the addition / removal mechanism 12, and the load value at that time is obtained by the load detection unit 10b. Compare the value with the mass of the weight 16 entered in advance,
It is determined whether or not the difference is within a predetermined value.

FIG. 5 shows a program for shifting the calibration time T ₀ later. In the procedure shown in the figure, when started, first, in step s20, the calibration operation is automatically performed at the calibration time T ₀ , and thereafter, when the scale is used, between the calibration time T ₀ and the start of use. Time interval T _a
Is calculated. This time interval T _a is calculated by the calibration time T
_{Since 0} is known and the initial use is specified by the procedure shown in FIG. 3, it can be easily calculated from the output of the clock 14i.

Once the time interval T _a has been determined, step s
At 21, it is determined whether the time interval T _a is greater than 0 and less than 2 (hours). If it is determined that the time interval T _a is within this range, the calibration time T a _The procedure ends without modifying ₀ . If the scale is used within about 2 hours from the calibration, the reliability of the calibration is substantially ensured. Therefore, the calibration standard of 2 hours set here is corrected at the calibration time T _0. I try not to.

On the other hand, in step s21, the time interval T _a is 2
When it is determined that the above is the case, the process proceeds to step s22, it is determined whether the time interval T _a is larger than 2 and smaller than 6 (hours), and the time interval T _a is within this range. If it is determined to be within the range, step s23
Then, 1 (hour) is added from the calibration time T ₀ , a new calibration time is set to T ₂ , and the procedure ends.

The criteria of 6 hours set here is that if the balance is not used even after about 6 hours from the calibration,
Since the reliability of calibration will be substantially reduced, the calibration time will be improved by shifting the next calibration time later so that the scale will be used within at least 5 hours after calibration. It is something to try. If the calibration time is shifted later in step s23, ≤T _a
When ≧ 6, I decided to shift the calibration time by 1 hour for the time being and see the situation, and if it is used at the same time the next day, it will be 1 more.
It will be time lag and will be calibrated 2 hours before. In this case, 1 hour is for the time being because the next day may be used before that, so if it is suddenly shifted by T _a -1 hour, it may be in use at that time. .

When it is determined in step s22 that the time interval T _a is 6 or more, the process proceeds to step 24, and in step s24, the number of days when the time interval T _a is 6 hours or more continues for 3 days or more. If it is determined that it has been continued for 3 days or more in this step, a completely different calibration time T ₃ is set by subtracting 1 hour from the use start time in step s25. , The procedure ends.

If it is determined in step 24 that the continuation is within 3 days, the correction of the calibration time T ₀ is suspended in step s26 and the procedure ends. Here, the reason why step 24 is provided is, for example, when the electronic scale is moved to a place where the usage situation is completely different, or when the electronic scale is exported overseas with a time difference.
It is assumed that the built-in clock 14i and the local time are significantly different, and the usage status of the balance is observed for a certain number of days (set to 3 days in the embodiment), and the calibration time T
_The calibration time T ₃ is set before the use start time after the period when it is determined that the correction of ₀ is appropriate.

If the calibration time T ₀ is used before a certain number of days (three days are set in the embodiment) has elapsed, the correction of the calibration time T ₀ may be suspended, for example, recently. This kind of procedure is provided because day-long vacation is adopted by most companies and it is expected to be used at the same time as before after vacation. Now, according to the electronic scale employing the above-described procedure, first, basically, the calibration operation is automatically performed at the set calibration time T ₀ . At this time, when the calibration stop condition such as the use of the balance or the sudden change of the power supply voltage and the environmental condition is satisfied, the automatic calibration operation is inconvenient. Therefore, even if the calibration time T ₀ is reached, the automatic calibration operation is stopped. To be done.

Further, by calculating the time interval T _a from the calibration time T ₀ which is set in advance until the first use start and on a daily basis, in response to the magnitude of the time interval T _a, the calibration time T ₀ Since it is shifted back and forth, the calibration time is changed according to the usage status of the electronic scale, and the calibration operation can be performed immediately before it is used as much as possible.

[0038]

As described above in detail in the embodiments,
According to the electronic scale of the present invention, the following effects can be obtained. The user of the balance does not need to memorize the time when the electronic scale is automatically calibrated, and the calibration is performed automatically and regularly, so that the calibration work and management of the scale can be performed very easily. Since the calibration of the electronic scale is always completed at the time corresponding to the latest usage situation, the measurement accuracy is ensured even if it is used at any time. Since the automatic calibration is stopped while the electronic scale is in use, the user is not interrupted by the measurement work. Since the calibration time is corrected according to the usage status of the scale, it is not necessary to set the clock built in the scale to the local time because it is in the city directly related to the actual time. Hardware does not need to be expensive because there is no need to store the usage status of the balance for a long period of time and very little memory capacity is required.

[Brief description of drawings]

FIG. 1 is a functional block diagram showing an embodiment of an electronic scale according to the present invention.

FIG. 2 is a block diagram showing hardware of an electronic scale according to the present invention.

FIG. 3 is a flow chart diagram for determining use / non-use of the electronic scale according to the present invention.

FIG. 4 is a flow chart when correcting the calibration time with the electronic scale according to the present invention.

FIG. 5 is a flow chart when correcting the calibration time with the electronic balance according to the present invention.

[Explanation of symbols]

 10 Electronic Scale Main Body 10a Dish 10b Load Detecting Unit 12 Weight Adjusting Mechanism 14 Control Unit 14a CPU 14d Nonvolatile RAM 14f Display 14g Printer 18 Environment Sensor 20 Voltage Sensor

Claims (2)

[Claims] 1. A built-in calibration weight, a load detecting means, an adding and removing means for loading or removing the calibration weight on the load detecting means, and a control signal to the adding and removing means at a preset calibration time. An electronic calibrator, which is provided with an automatic calibrating means for sending out and performing a calibration operation, in an electronic scale for measuring the weight of a measurement object loaded on the load detecting means, a use state detecting means for detecting the start of use of the electronic scale, An interval from the calibration time to the start of use is calculated in units of hours and / or days based on the detection value of the usage state detecting means, and the calibration time is shifted back and forth according to the size of the interval. An electronic scale comprising a calibration time correction means. 2. The electronic scale according to claim 1, wherein a calibration operation stop signal is sent to the automatic calibration means when a calibration stop condition such as during use of the balance or a sudden change in power supply voltage or environmental conditions is satisfied. An electronic scale having a stop means.