JPH0743196A - Stable time checking device for weighing signal in combined weighing machine - Google Patents

Abstract

PURPOSE:To self-diagnose whether a weighing signal outputted by a load detecting means is set in such a manner as to be read after a proper stable time or not by providing a weighing means for outputting the weighing signal, the load detecting means, and an arithmetic control means. CONSTITUTION:The weighing signal of a load detector 8-1 is supplied to an A/D converter 15 through a multiplexer after amplified, converted into a digital signal, and supplied to an arithmetic control part (CPU) 16. The CPU 16 successively inputs the digital weighing signal of the article supplied to each weighing hopper 6-1... when a prescribed starting signal is inputted from an operation set display part 17, conducts combinational operation on the basis of it, and determines the article to discharge. When the articles in feed hoppers 5-1... and weighing hoppers 6-1... aredischarged, the gate driving device 18 of a weighing unit A is driven by a driving circuit 19 to open and close the respective gates. Linear feeder 3-1... are driven by a vibration control circuit 20.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention self-diagnoses whether a weighing signal output from each load detector provided in a combination weigher is set to be read after an appropriate stabilization time has elapsed. The present invention relates to a stable time check device for weighing signals in a combination scale.

[0002]

2. Description of the Related Art FIG. 3 shows a conventional automatic combination scale. That is, in this automatic combination weigher, a crosshead feeder (article feeding device) 2 for supplying articles is provided on a dispersion feeder 1, and articles are supplied to the crosshead feeder 2 from a bucket feeder 100. Multiple units (n units) radially around the dispersion feeder 1
, Linear feeders 3-1 ... are provided, and when the vibrators 4-1 ... Vibrate, the articles supplied from the dispersion feeder 1 are conveyed to the tip side thereof. At the tip of the linear feeder 3-1, the feed hopper 5-
1 are provided, and the article can be held. Below these feed hoppers 5-1 ..., weighing hoppers 6-1 ... are provided respectively, and when these are empty, the gates 7-1 ... of the feed hoppers 5-1.
Is opened and articles are fed. These weighing hoppers 6-
1 ... are provided with load detectors 8-1 ..., respectively, and detect the weight value of the articles supplied to the weighing hoppers 6-1. The weight values of the articles in the weighing hoppers 6-1 ... Are variously combined, and a combination in which the total weight is within the allowable weight range is selected. That is, a combination calculation is performed to select from which weighing hopper the article is to be discharged. For example, when the weighing hopper 6-1 is selected, the gate 10-1 outside the weighing hopper 6-1 is opened, The articles are supplied to the lower packaging machine 14 through the lower split chute 12 and the inverted truncated cone-shaped collecting chute 13 of the weighing hopper 6-1.

[0003]

In such an automatic combination weigher, generally, high weighing accuracy and high-speed weighing (reducing the time required for weighing) are required, but it is difficult to satisfy both of them. That's right. That is, in order to obtain high weighing accuracy, for example, the stabilization time from the supply of articles to the weighing hoppers 6-1 ... to the stabilization of the weighing signal output by the load detectors 8-1. This is because the above stabilization time must be shortened in order to perform high-speed weighing. Therefore, when actually weighing articles with a combination weigher, for example, set the desired weighing accuracy (allowable weight range) to the combination weigher, and then set the shortest stable time that can obtain this weighing accuracy. Is set on the combination scale. However, although the shortest stable time that can obtain a desired weighing accuracy theoretically exists, it is very time-consuming and difficult to accurately obtain this shortest stable time. Because the time when the weighing signal stabilizes is the property of the article, the load detector 8-1 ...
This is because it is determined by various factors such as the natural frequency and the like, and it is difficult to accurately grasp each of these factors.

The present invention is an apparatus for checking the stability time of a weighing signal in a combination scale capable of self-diagnosing whether or not the weighing signal output by the load detector is set to be read after an appropriate stabilization time has elapsed. The purpose is to provide.

[0005]

According to a first aspect of the present invention, there is provided a weighing means for weighing a supplied article and outputting a weighing signal, and the weighing signal outputted at a weighing timing after a lapse of a predetermined stabilization time. And a combination selection means for selecting a combination in which the total value of the weighing signals is equal to or close to a predetermined target weight from these combinations, and the combination scale is combined by the combination selection means. Storage means for storing the weighing signal that has not been selected and the data indicating the weighing means that has output the weighing signal, and the weighing means stores the weight of the article corresponding to the weighing signal stored in the storage means. Re-weighing signal reading means for re-weighing and reading the weighing signal output by this re-weighing at the next and subsequent weighing timings; Whether the difference between these two weighing signals is within a predetermined allowable range by comparing the reweighing signal read by the signal reading means with the weighing signal corresponding to the reweighing signal stored in the storage means. It is characterized by comprising a weighing signal determining means for determining whether or not there is output, and an output means for outputting a signal indicating the determination result of the weighing signal determining means.

A second aspect of the present invention is to combine the weighing means for weighing the supplied articles and outputting a weighing signal and the weighing signal outputted at the weighing timing after a predetermined stable time has elapsed in various combinations. And a combination selection means for selecting a combination in which the total value of the weighing signal is equal to or close to a predetermined target weight from among the combinations, the combination scale not selected by the combination selection means. Storage means for storing a weighing signal and data indicating the weighing means that output the weighing signal, and the weighing means weighs the weight of the article corresponding to the weighing signal stored in the storage means again, and Re-weighing signal reading means for reading the weighing signal output by the weighing at the next and subsequent weighing timings, and the re-weighing signal reading means The read re-weighing signal is compared with the re-weighing signal corresponding to the re-weighing signal stored in the storage means to determine whether the difference between the two re-weighing signals is within a predetermined allowable range. And a stabilization time determination means for determining whether or not the length of the stabilization time is appropriate based on the determination result of the measurement signal determination means. is there.

According to a third aspect of the present invention, in the second aspect of the present invention, when the stable time determining means determines that the stable time length is inappropriate, the stable time changing means changes the stable time length. Is provided.

[0008]

According to the first aspect of the present invention, the weighing means measures the weight of the supplied articles and outputs a weighing signal, and the combination selecting means outputs various weighing signals at the weighing timing after a predetermined stable time has elapsed. The combination of which the total value of the weighing signals is equal to or close to the target weight is selected from among these combinations, but the storage means stores the weighing signals not selected as the combinations. Then, the weighing means re-weighs the weight of the article corresponding to the weighing signal stored in the storage means, the weighing signal output by this re-weighing is read at the next and subsequent weighing timings, and the read re-weighing is read. The signal and the re-weighing signal are compared with the corresponding weighing signal, and the weighing signal determining means determines whether or not the difference between the two weighing signals is within an allowable range. Then, the output means outputs a signal indicating this determination result. In other words, the re-weighing signal is a weighing signal read after a lapse of a time longer than the set stabilization time (at a predetermined weighing timing after the next time), and thus the re-weighing signal is close to the true weight of the article. Whether the currently set stabilization time is an appropriate length by, for example, the operator or the like grasping the signal indicating the comparison result between this reweighing signal and the corresponding weighing signal. It can be determined whether or not.

According to the second invention, the re-weighing signal is compared with the weighing signal corresponding to the re-weighing signal, and the re-weighing signal is compared with the re-weighing signal.
The weighing signal determination means determines whether or not the difference between the two weighing signals is within the allowable range, and based on the determination result, the stabilization time determination means determines whether or not the currently set stabilization time is appropriate. can do. That is, the stabilization time determination means determines, for example, that the number of determination results that there is a difference is a predetermined allowance based on the number of determination results that the two weighing signals are different and the number of determination results that the two weighing signals are not different. If it is out of the range, or if the ratio of the number of judgment results that there is a difference to the number of judgments is outside the predetermined allowable range, the length of the currently set stabilization time It is possible to determine that the weight cannot be weighed with an accuracy within the allowable range and the currently set stable time is inappropriate.
In the opposite case, that is, when the number or ratio of the determination results that there is a difference is within the allowable range, it is possible to determine that the stabilization time is appropriate.

According to a third aspect of the present invention, in the second aspect, when the stable time determination means determines that the currently set stable time is inappropriate, the stable time can be changed. That is, for example, the re-weighing signal is compared with a weighing signal corresponding to the re-weighing signal, the difference between the two weighing signals is out of the allowable range, and the stable time determining means is currently set. When it is determined that the stabilization time is inappropriate, the setting is changed so that the stabilization time is longer than the currently set time. If the difference between the two weighing signals is within the allowable range and the stabilization time determination means determines that the currently set stabilization time is appropriate, the currently set stabilization time is not changed. I will.

[0011]

EXAMPLE In this example, the automatic combination weigher shown in FIG. 3 is applied with a stable time check device for weighing signals in the combination weigher of the present invention (hereinafter referred to as stable time check device). In addition, the dispersion feeder 1, the linear feeder 3-1, ..., The vibrator 4-1 ...
., Feed hopper 5-1 ..., weighing hopper 6-1.
The load detectors 8-1, ... Have the same configuration as described in the conventional example, and thus detailed description thereof will be omitted.

However, this combination weigher has a weighing unit A as shown in FIG. Although not shown in the figure, a plurality of sets (n sets) of weighing units A are actually provided. The weighing unit A has a weighing hopper 6-1 equipped with a load detector 8 and a feed hopper 5-1. The weighing signal of the load detector 8-1 is amplified by an amplifier (not shown) and then supplied to the A / D converter 15 of the control unit B via a multiplexer (not shown), where a digital signal is supplied. And is supplied to the arithmetic control unit (microprocessor (CPU)) 16. The arithmetic control unit 16 is
When a predetermined activation signal is input from the operation setting display unit 17, the digital weighing signals of the articles supplied to the weighing hoppers 6-1 ... Are sequentially input, a combination calculation is performed based on these signals, and the articles are discharged. Determine the goods to be shipped.

The feed hoppers 5-1 ...
And when discharging the articles in the weighing hopper 6-1 ...
Each gate is opened and closed by driving the gate drive device 18 of the weighing unit A by the drive circuit 19. Further, the vibration control circuit 20 allows the linear feeder 3-
1 is driven.

Further, the arithmetic control unit 16 includes a storage unit 21,
The timer 22 is connected and the operation setting display unit 1
7 is connected. The storage unit 21 has a RAM and a ROM, and various operating constants and the like are written in the RAM, and a program corresponding to a flowchart described later is written in the ROM. The timer 22 is made up of a plurality of counters each counting down a clock pulse from a set value that is proportional to the set time, and when the count value becomes 0, the set time is reached. In addition, the operation setting display unit 17 can set various operation constants necessary for the operation of the combination weigher, and can perform ON / OFF operation of the operation. Further, an alarm or the like can be displayed, data can be transmitted, and a printing unit (not shown) connected to this can be operated.

FIG. 5A shows the combination scale No. It is a time chart which paid its attention to one weighing hopper 6-1. When the gate 7-1 of the feed hopper 5-1 is opened, articles are put into the weighing hopper 6-1 from the feed hopper 5-1.
The weight of the article is weighed at the weighing timing A ₁ after the preset predetermined stabilization time has elapsed since the article was loaded into the weighing hopper 6-1. Then, the weighing signals from the weighing hoppers are combined to perform the above-described combination calculation, and the gate of the selected weighing hopper is opened to convey the article to the packaging machine 14. This completes one cycle of the combination weighing, and this weighing cycle is sequentially repeated to perform the combination weighing of the articles.

The stable time check device is composed of an arithmetic control unit 16, a timer 22, a storage unit 21, and a program previously written in the storage unit 21, and the like.
The storage means, the reweighing signal reading means, the weighing signal determining means, the stable time determining means, the alarm means, and the stable time changing means are provided.

The storage means participates in the combination weighing, but the weighing signals not selected in the combination and the load detectors 8-1 ... (Weighing hopper 6-1.
It has a function of storing the data indicating () in the storage unit 21 and deleting the weighing signal selected for the combination and the data of the load detector that outputs the weighing signal from the storage unit 21. Therefore, the storage unit 21 stores the weighing signal for the articles stored in the weighing hopper without being selected as the combination and the data indicating the load detector that outputs the weighing signal. In addition, when the weight of the articles accommodated in the weighing hopper is weighed for the second time, but the second weighing signal is not selected as the combination, the first weighing signal is erased and the second weighing signal is deleted. Memorize the second weighing signal. However, the first weighing signal may be left in the memory and the second weighing signal may be deleted.

The re-weighing signal reading means outputs the weighing signal output by weighing the weight of the article corresponding to the weighing signal stored in the storage unit 21 again by the weight detector 8-1. , It has a function to read at the next timing of weighing.

The procedure for the reweighing signal reading means to read the weighing signal will be described with reference to FIG. 5 (b). This figure shows the combination scale No. It is a time chart which paid its attention to two weighing hoppers 6-2. Articles are fed into the weighing hopper 6-2 from the feed hopper 5-2, and the articles are fed into the weighing hopper 6-2 at a weighing timing B ₁ after a preset predetermined stabilization time T _{A has} elapsed from when the articles were fed into the weighing hopper 6-2. Weigh the Then, the weighing signals from the weighing hoppers are combined to perform a combination calculation, and the gate of the selected weighing hopper is opened to convey the article to the packaging machine 14. However, No. The articles stored in the weighing hopper 6-2 of No. 2 are not selected as the combination, 2 weighing hopper 6-
It is still stored in No. 2 and the weighing is read again by the re-weighing signal reading means at the next weighing timing B ₂ . This reweighing signal is 2 is a signal obtained after a sufficient time has elapsed since the articles were loaded into the second weighing hopper 6-2 (after the stabilization time T _B ), and is compared with the weighing signal obtained at the weighing timing B _1. Can be said to be very close to the true weight of the article.

The weighing signal determination means compares the re-weighing signal read by the re-weighing signal reading means with the weighing signal corresponding to the re-weighing signal stored in the storage unit 21, and compares these two weighing signals. The absolute value of the difference is a predetermined boundary value α
It has a function of determining whether or not the following. That is,
When the absolute value of the difference between the two weighing signals is less than or equal to the boundary value α, it is determined that there is no difference, and when the absolute value of the difference is larger than the boundary value α, it is determined that there is a difference.

The stable time determination means determines whether or not the length of the stable time is appropriate based on the determination result of the weighing signal determination means. That is, the number of determination results (the number of defects) that the difference between the re-weighing signal by the weighing signal determination means and the two weighing signals stored in the storage unit 21 is different (the number of defects) and the number of the determination results that there is no difference (good number ), The stability time that is currently set when the ratio of the number of judgment results (the number of failures) to the number of judgments (the number of failures + the number of good times) is greater than or equal to the boundary value β. With the length of T _A , the weight of the article cannot be measured with an accuracy within the allowable range, and it is determined that the currently set stabilization time T _A is inappropriate. In the opposite case, that is, when the ratio of the determination result that there is a difference is less than the boundary value β, the currently set stabilization time T _A
Is determined to be appropriate. That is, the stability time determination means is
It works as a self-diagnosis function for judging whether or not the currently set stable time T _A is an appropriate length.

The alarm means has a function capable of outputting an alarm signal based on the determination result of the weighing signal determination means. That is, when the weighing signal determining means determines that the absolute value of the difference between the re-weighing signal and the weighing signal stored in the storage unit 21 is larger than the boundary value α, an alarm signal is output and an operation setting is made to that effect. The alarm is generated by the alarm device (not shown) while being displayed on the display unit 17. When the weighing signal determination means determines that the absolute value of the difference between the two weighing signals is less than or equal to the boundary value α, no warning signal is output, and accordingly, nothing is displayed on the operation setting display unit 17. , No alarm sound is generated.

The stable time changing means has a function of changing the length of the stable time by a predetermined time when the stable time determining means determines that the length of the stable time is inappropriate. . However, instead of changing the length of the stable time by a predetermined time, the stable time may be changed by a predetermined ratio with respect to the currently set stable time.

Next, the operation procedure of the combination weigher and the stable time check device will be described with reference to the flow charts of FIGS. Note that FIG. 1 is a flowchart showing details of the operation procedure of the stable time check device. First, FIG.
As shown in FIG. 5, the operator operates the operation setting display unit 17 to set various items such as a stable time, a target weight of articles to be weighed in combination, an allowable weight range for selecting a combination, and boundary values α and β (described later). The operating constants and operating parameters are set, and the start switch is turned on (S100). Then,
Driving and stopping the linear feeder 3-1 ...
The gates 7-1 of the feed hoppers 5-1 are opened and closed, etc., and the weights of the articles are measured by the load detectors 8-1 after the lapse of a predetermined stabilization time (S10).
2). Then, at the timing of the combination calculation (S104), the stable time check device checks the stable time (S106). The operation procedure of the stable time check device will be described later. Next, the arithmetic control unit 16
Performs a combination calculation based on the weighing signals supplied from the load detectors 8-1 ... (S108). And
A set in which the total value of the weighing signals is the closest to the target weight and within the allowable weight range is selected (S110), and the articles forming the selected set are discharged from the corresponding weighing hopper at a predetermined timing. (S112, S114)). These discharged articles are packaged by the packaging machine 14 as one pack. However, if it is determined in step 110 that there is no suitable combination (NO),
Returning to step 102, the empty weighing hopper 6 is fed with the items to be weighed and the number of weighing signals participating in the combination is increased. Then, of the weighing signals selected for the combination, the weighing signal stored in the storage unit 21 and the data indicating the weighing hopper 6 that has stored the article of this weighing signal are deleted from the storage unit 21, and the "good number" , The count value of the counter that counts the “number of failures” is cleared to 0 (S11
6). The counter for counting the “good count” and the “defective count” will be described later. This completes one cycle of the operation of the combination weigher and the stable time check device, and when one cycle is completed, the process returns to step 100 and the above-mentioned and later-described operations are repeated.

Next, the operation procedure of the stable time check device will be described with reference to FIG. The flowchart shown in FIG. 1 shows details of step 106 in FIG. This stability time check device is, for example, in No.
1-No. The weight of the articles supplied to a plurality of weighing hoppers of the n weighing hoppers 6-1 to 6-n is weighed and is not selected as a combination among the weighing signals obtained thereby. The measured signal is stored in the storage unit 21. Then, the weight of the article corresponding to the weighing signal stored in the storage unit 21 is weighed again, the weighing signal output by this weighing again is read at the next weighing timing, and the reweighing obtained by this reading is read. The signal and the previous weighing signal stored in the storage unit 21 are compared to determine whether or not the absolute value of the difference is larger than the boundary value α. Then, when the ratio of the number of times it is determined that the absolute value of the difference between the two weighing signals is larger than the boundary value α is equal to or larger than the boundary value β, the set value is changed so as to lengthen the stabilization time. This makes it possible to check an inappropriate stabilization time and change it to an appropriate stabilization time.

That is, as shown in FIG. If the weighing by the weighing hopper 6-1 of No. 1 is completed (YES
When it is determined (S200), this No. The storage unit 2 stores the weighing signals of the articles weighed by the weighing hopper 6-1.
It is stored in 1 (S202). And No. The articles stored in the weighing hopper 6-1 of No. 1 are weighed at the weighing timing before the previous time, and the weighing signal is already stored in the storage unit 2.
It is determined whether or not it is stored in 1 (S204). As a result, the No. It is possible to determine whether it is the first time or a plurality of times (re-weighing) that the weight of the articles accommodated in one weighing hopper 6-1 has been measured. And No. When the weighing signal of the articles accommodated in the first weighing hopper 6-1 is stored in the storage unit 21 and it is determined that the present weighing is a plurality of times (reweighing) (YES), the storage unit The absolute value of the difference between the weighing signal obtained at the weighing timing before the previous time stored in 21 and the re-weighing signal obtained at this weighing is calculated, and the absolute value of this difference is larger than the boundary value α. It is determined whether or not (S206). If it is determined that the absolute value of the difference between the weighing signal obtained before this time and the weighing signal obtained this time is larger than the boundary value α, the self-diagnosis that the currently set stabilization time is short is inappropriate. When it is determined that the absolute value of the difference is equal to or less than the boundary value α, it is possible to perform self-diagnosis that the set stabilization time is appropriate. This is because the weighing signal obtained before the previous time is obtained at the weighing timing B ₁ after the stabilization time T _A shown in FIG. 5B has elapsed, and the weighing signal obtained this time is the stabilization time T _B. (T _a <T _B) since those obtained at measuring timing B ₂ after a lapse of,
This is because the stable time T _A can be said to be an appropriate length when the absolute value of the difference between the two weighing signals is within the allowable range of the boundary value α or less.

When it is determined that the absolute value of the difference between the two weighing signals is larger than the boundary value α and the result is NO, an alarm sound (not shown) is generated and an alarm sound is generated.
Displays that the stabilization time is inappropriate on the operation setting display,
The count value of the counter that counts the number of defects is incremented by 1 (S208). However, when the absolute value of the difference between the two weighing signals is equal to or less than the boundary value α and YES is determined, the count value of the counter for counting the number of good times is incremented by 1 (S210). Each counter that counts the number of passes and the number of passes is provided in the arithmetic control unit 16. In this way, No. The currently set stable time can be checked (self-diagnosis) based on the weighing signal of the articles supplied to the first weighing hopper 6-1. Similarly to this, the No. No. 2 weighing hopper 6-2 to No. The currently set stable time is checked based on the weighing signal of the articles supplied to the n weighing hoppers 6-n (S212 to S212).
222).

However, in FIG. 1 and No. n
The flowchart of the operation procedure for checking the stable time based on the weighing signal of the articles supplied to the weighing hopper of No. 2 to No. The flow chart regarding the weighing hopper (n-1) is omitted because it is equivalent to the above. The steps 206, ..., 218 correspond to the weighing signal determining means. As described above, the stable time is checked by the weighing signal stored in the storage unit 21 without being selected as a combination, and even if the weighing signal stored in the storage unit 21 is combined. Since the storage unit 21 is erased when it is selected, the stable time is not checked for the weighing signal. It is step 116 shown in FIG. 2 that the data indicating the weighing signal selected for this combination and the load detector corresponding thereto is deleted from the storage unit 21.

Next, (defective count count value) / (defective count count value + good count count value) = defective rate is calculated to determine whether the defective rate is smaller than the boundary value β. (S224), the defect rate is the boundary value β or more, and YES
If it is determined that the setting is, the setting is changed so that the currently set stable time is lengthened (S226). When changing the stabilization time, how long the stabilization time should be
It is necessary to set it so that it will be increased by an appropriate time depending on the length of the stabilization time.

However, in step 224, when it is judged that the defective rate is smaller than the boundary value β and is NO,
Do not change the currently set stabilization time, and use that stabilization time from the next time. This step 224 corresponds to the stable time determination means.

As described above, according to this stability time check device, the ratio of the number of times it is determined that the difference between the weighing signal obtained at the weighing timing before the previous time and the re-weighing signal obtained this time is outside the allowable range (defective) Rate) is equal to or greater than the boundary value β, the self-diagnosis is made that the weight of the article cannot be weighed with an accuracy within the allowable range within the currently set stabilization time, and the stabilization time is set to a value longer than the currently set time. Can also be changed in a long time. Thus, even if the currently set stabilization time is inappropriate, the setting can be automatically changed to an appropriate stabilization time. As a result, it is possible to automatically operate the combination weigher at a relatively high weighing speed among the weighing speeds at which the weighing accuracy set by the operator can be obtained.

However, in the above embodiment, as shown in step 218 of FIG. 1, the weighing signal obtained at the weighing timing before the previous time (the weighing signal stored in the storage unit 21) and the weighing signal at this weighing timing are obtained. It is determined whether or not there is a difference between the two weighing signals by calculating the absolute value of the difference between the re-weighed signals and determining whether or not the absolute value of the difference is less than or equal to the boundary value α. It is also possible to determine whether or not there is a difference between the two weighing signals by calculating the ratio of these two weighing signals and determining whether this ratio is less than or equal to a predetermined boundary value α _1. .

In the above embodiment, as shown in steps 224 and 226 of FIG. 1, when the defective rate is less than the boundary value β, the setting of the stable time is not changed.
When the defective rate is less than a predetermined boundary value β ₁ (β> β ₁ ), the setting can be changed to shorten the stabilization time. As a result, it is possible to perform weighing with a certain fixed weighing accuracy, and it is possible to make the weighing speed (speed required for weighing) higher than a certain fixed speed.

Further, in the above embodiment, as shown in step 224 of FIG. 1, the ratio of the number of determination results (number of defects), which is considered to be different, to the number of determinations (number of defects + number of good defects) is When it becomes equal to or more than the boundary value β, it is determined that the currently set stable time T _A is inappropriate.
Instead of this, when the number of determination results (the number of defects) that there is a difference is equal to or larger than a predetermined boundary value β ₁ , it is determined that the currently set stabilization time T _A is inappropriate. May be.

Further, in the above embodiment, the stability time checking device is applied to the automatic combination weigher capable of automatically supplying the goods to the weighing hopper, but the semi-automatic combination machine for manually supplying the goods to the weighing hopper is used. It can be applied to scales.

In the above embodiment, the defective rate is equal to or larger than the boundary value β in step 224 shown in FIG.
If it is determined to be S, the setting is changed so as to lengthen the currently set stable time at step 226. However, at the same time, the setting is changed so as to lengthen the currently set stable time at step 226. The operation setting display unit 17 may display an alarm and the changed stabilization time.

[0037]

The stable time check device for the weighing signal in the combination weigher of the first invention compares the re-weighing signal with the weighing signal corresponding to the re-weighing signal and allows the difference between the two weighing signals. The measuring signal determining means for determining whether or not it is within the range, and the output means for outputting the determination result are provided. Thus, for example, when the operator reads this determination result and determines that the currently set stabilization time is inappropriate, the setting can be changed from the inappropriate stabilization time to an appropriate stabilization time. There is. As a result, a relatively short stabilization time that can obtain the desired weighing accuracy can be set in the combination weigher, and as a result, the operator can very easily obtain the desired weighing accuracy among the weighing speeds. Thus, the combination scale can be operated at a relatively high measurement speed.

According to a second aspect of the present invention, there is provided a weighing signal stabilization time check device for a weighing signal, wherein the weighing signal determining means of the first aspect of the present invention and an appropriate stabilizing time for the weighing instrument are determined based on the determination result of the weighing signal determining means. And a stable time determination means for determining whether or not it is set. Therefore, the operator, based on the determination result by the stability time determination means of whether the stabilization time set in the combination scale is appropriate,
There is an effect that an inappropriate stabilization time can be changed to an appropriate stabilization time very easily and the appropriate stabilization time can be maintained as it is. As a result, there is an effect that the combination weigher can be operated at a relatively high weighing speed among the weighing speeds at which desired weighing accuracy can be obtained.

The weighing signal stabilization time check device in the combination weigher according to the third aspect of the present invention is set at present when the stability time determination means for self-diagnosing the stabilization time and an inappropriate stability time is set in the combination weigher. Stable time changing means for changing the setting of the stable time toward the appropriate stable time,
Is equipped with. Therefore, the currently set stabilization time is outside the allowable range, and even if it is inappropriate, the stabilization time is automatically changed to an appropriate stabilization time, and as a result, the desired weighing accuracy is automatically obtained. There is an effect that the combination weigher can be operated at a relatively high weighing speed among the available weighing speeds.

[Brief description of drawings]

FIG. 1 is a flowchart showing an operation procedure of a weighing signal stable time check device in a combination weigher according to an embodiment of the present invention.

FIG. 2 is a flowchart showing an operation procedure of a combination weigher provided with the same stable time check device of the same embodiment.

FIG. 3 is a schematic cross-sectional view of the automatic combination weigher of the embodiment.

FIG. 4 is a block diagram showing an electric circuit of a combination weigher including the same stable time check device of the same embodiment.

FIG. 5 is a timing diagram showing a stabilization time and a metering timing of the embodiment.

[Explanation of symbols]

 6 weighing hopper 8 load detector 16 control calculation unit 17 operation setting display unit 21 storage unit

Claims (3)

[Claims] 1. A weighing means for weighing the weight of a supplied article and outputting a weighing signal, and the weighing signal outputted at a weighing timing after a lapse of a predetermined stabilization time is combined in various ways, and a combination thereof is provided. A combination weighing means for selecting a combination in which the total value of the weighing signals is equal to or close to a predetermined target weight, the weighing signal not selected by the combination selecting means and the weighing signal Storage means for storing data indicating the weighing means that has output the weighing signal, and the weighing means again weighs the weight of the article corresponding to the weighing signal stored in the storage means, and outputs by this weighing again. The re-weighing signal reading means that reads the measured weighing signal at the next and subsequent weighing timings, and the re-weighing signal reading means read A weighing signal for comparing the weighing signal with the weighing signal corresponding to the re-weighing signal stored in the storage means to determine whether the difference between these two weighing signals is within a predetermined allowable range. Determination means, output means for outputting a signal indicating the determination result of the weighing signal determination means,
An apparatus for checking a stable time of a weighing signal in a combination scale, comprising: 2. A weighing means for weighing a supplied article and outputting a weighing signal, and the weighing signal outputted at a weighing timing after a predetermined stabilization time has been variously combined, among these combinations. A combination weighing means for selecting a combination in which the total value of the weighing signals is equal to or close to a predetermined target weight, the weighing signal not selected by the combination selecting means and the weighing signal Storage means for storing data indicating the weighing means that has output the weighing signal, and the weighing means again weighs the weight of the article corresponding to the weighing signal stored in the storage means, and outputs by this weighing again. The re-weighing signal reading means that reads the measured weighing signal at the next and subsequent weighing timings, and the re-weighing signal reading means read A weighing signal for comparing the weighing signal with the weighing signal corresponding to the re-weighing signal stored in the storage means to determine whether the difference between these two weighing signals is within a predetermined allowable range. A weighing signal in a combination scale, comprising: a determining unit; and a stabilization time determining unit that determines whether or not the length of the stabilization time is appropriate based on the determination result of the weighing signal determining unit. Stability time check device. 3. The stability time check device for a weighing signal in a combination weigher according to claim 2, wherein the stability time determination means determines the length of the stabilization time when the stability time determination means determines that the stabilization time is inappropriate. Time stabilizing device for weighing signals in a combination weigher, characterized in that stable time changing means for changing the height is provided.