JPS6151726B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a digital display type counting scale that calculates and digitally displays the number of objects to be measured based on their total weight.

When measuring the number of objects to be measured using a digital display type counting scale (hereinafter simply referred to as a counting scale), first place multiple samples of the object to be measured on the weighing pan, and then enter the number N of the same samples from the operation section. Enter. As a result, the calculation [sample weight W÷N] is performed inside the counting scale, and as a result, the unit weight U of the object to be measured is determined, and this unit weight U is displayed on the display section. Next, when the object to be measured is placed on the weighing pan, the calculation [weight of the object W ₁ ÷ U] is performed inside the counting scale, and the result of this calculation, that is, the number of objects to be measured, is displayed. Displayed by department.

By the way, in the above-mentioned counting scale, the weight (analog voltage) of the sample measured by a load cell or the like is converted into a digital signal by an A/D (analog/digital) converter, and the unit weight is calculated based on this digital signal. Although U is calculated, a quantization error occurs when converting it into a digital signal, which causes an error in measuring the number of objects to be measured. For example, if the weight of the sample is 25.3 [g] and the number of digits of the A/D converter is 2, then
The converter outputs the numerical value "25", resulting in a quantization error of 0.3 g. Furthermore, in this case, a quantization error of up to ±0.5 [g] may occur. For this reason, for example, if you want to keep the error in measuring the number of objects to be measured within 1%, you can calculate Samples are required. In other words, if the unit weight U of the object to be measured is calculated from a sample of 50 [g] or more, and the number of objects to be measured is calculated based on this calculated unit weight U, the error in number measurement can be kept within 1%. It can be done. Therefore, conventional counting scales are provided with a display that indicates a sample shortage, and if the sample weight is insufficient, the sample is added according to the instructions on the display.

However, in such conventional counting scales, it is necessary to add the sample to the weighing pan while checking the display and counting the number, which makes it very difficult to add the sample, especially when the unit weight of the sample is small. There was a problem that was troublesome and easily caused counting errors.

The present invention was made to solve this problem when there is a shortage of samples, and when there is a shortage of samples, the number of samples to be added is displayed using a numerical display.

An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a block diagram showing the configuration of a counting scale according to the present invention. In this figure, reference numeral 1 is a weighing pan, and the weight of the object or sample placed on the weighing pan 1 is detected by a weight converter 3 composed of a load cell or the like, and the weight is measured. The value is output to the A/D converter 4 as an analog voltage. The A/D converter 4 converts the analog voltage supplied from the weight converter 3 into a digital signal, and the central processing unit (hereinafter abbreviated as CPU) 5
Output to. The CPU 5 is composed of a microcomputer, for example, and performs various calculations described below, and the calculation results are displayed on the display 6 (numeric display).
Displayed by. Further, the operation unit 7 includes a numeric keypad and a plurality of function keys, the output of which is supplied to the CPU 5.

Next, the operation of this counting scale will be explained with reference to the flowchart shown in FIG.

First, when the operator places N samples of the object to be measured on the weighing pan 1 (step S1), analog voltages corresponding to the weights of these N samples are output from the weight converter 3, and A/D conversion is performed. It is supplied to the container 4. The A/D converter 4 converts the supplied analog voltage into a digital signal and outputs it to the CPU 5 as weight data W corresponding to the weights of N samples. At this time, when the operator simultaneously inputs the number N of samples from the operation unit 7, the number N is supplied to the CPU 5. The CPU 5 first performs the calculation W/N based on the number N supplied from the operation unit 7 and the weight data W supplied from the A/D converter 4, thereby determining the unit weight U of the sample (step S2 ). Next, the CPU 5 compares the preset reference sample weight A with the weight data W, and thereby determines whether or not there is a sample shortage (step S3). In this case, the reference sample weight A is the minimum sample weight required to reduce the measurement error of the number of objects to be measured due to the quantization error of the A/D converter 4 to a predetermined percentage or less (as described above). 50 [g]). If the above-mentioned judgment result is W≧A (if there is no shortage of samples), the unit weight U is displayed on the display 6 (step S4), and the number of objects to be measured can be counted. Further, in this case, the measurement error can be kept below the predetermined ratio described above.

On the other hand, the result of determining whether the sample is insufficient is W<A
In the case (in the case of insufficient samples), the CPU 5 performs the calculation (A-W)/U to calculate the number M of samples to be added. The obtained number of samples M is then displayed on the display 6 (step S5). Here, the operator adds the displayed number of samples M to the weighing pan (step S6). As a result, the number of samples on the weighing pan becomes N+M, and the analog voltage corresponding to this number of samples N+M is output from the weight converter 3, and converted into weight data W' by the A/D converter 4 as a digital signal. CPU
5. The CPU 5 calculates the unit weight U' again by performing the calculation W'/(M+N) (step S2), and compares the weight data W' with the reference sample weight A to determine whether or not there is a sample shortage. (Step S3). in this case,
Naturally, there is no shortage of samples, and therefore the unit weight
U' is displayed on the display 6 (step S4),
It becomes possible to count the number of objects to be measured.

The operating section 7 is equipped with a changeover switch, and when this changeover switch is turned to one side, it becomes impossible to measure the number of pieces when there is a shortage of samples, and when it is turned to the other side, it becomes impossible to measure the number of pieces when there is a shortage of samples. Measurement becomes possible ("END2" in Figure 2).

Next, a second embodiment of the present invention will be described with reference to FIG. Note that this second embodiment is
If the CPU 5 is composed of a microcomputer, this can be implemented by simply changing the program. Further, in FIG. 3, steps corresponding to those in FIG. 2 are given the same reference numerals.

If the number of missing samples is displayed in step S5 in FIG. It may also be placed on a plate. The second embodiment is constructed taking such a case into consideration.

That is, when the number of missing samples is displayed in step S5 in FIG. 3, the operator normally places an amount of sample considered to correspond to the number of missing samples on the weighing pan (step S8). If the number of added samples is, for example, _N1 , the A/D converter 4 outputs weight data _W1 corresponding to (N+ _N1 ) samples. The CPU 5 compares this weight data _W1 with the reference sample weight A (step S8). If A≦W ₁ , steps S2→S3→S4 are executed in sequence, and as a result, the unit weight U ₁ based on the number of samples (N+N ₁ ) is
is displayed. If A>W ₁ , the calculation (A-W ₁ )/U is performed again in step S5, and the number of missing samples obtained thereby is displayed. Based on this displayed number of missing samples,
The operator adds the sample again (step S
8). Thereafter, the same process is repeated, and when the sample shortage is resolved, the number of objects to be measured can be counted.

In addition, in the first and second embodiments described above,
A buzzer or the like may be used to notify the operator that the sample shortage has been resolved. Furthermore, when the sample is insufficient, a numeric display may be used to display "〓〓〓" (Add).

As explained above, according to the present invention, the processor determines whether or not there is a shortage of samples, and if there is a shortage of samples, the display displays the number of samples to be added. This has the advantage that samples can be added without error and in a short time.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing the configuration of an embodiment of this invention, FIG. 2 is a flowchart for explaining the operation of the embodiment shown in FIG. 1, and FIG. It is a flow chart for explanation. 1... Weighing pan, 3... Weight converter, 4... A/D
Converter, 5...Central processing unit (CPU), 6...Display unit, 7...Operation unit.

Claims (1)

[Claims] 1. A weight converter that converts the weight of an object to be measured on a weighing pan into an analog voltage, and an analog voltage converter that converts the analog voltage output from the weight converter into a digital signal and outputs it as weight data. A counting scale having a digital converter is provided with a processing device and a display section, and when an operator places a sample on the weighing pan and inputs the number N of the same samples from the operation section, the processing device・Calculate W/N based on the weight data W output from the digital converter and the number N of the samples, calculate the unit weight U of the samples, and calculate the W and the reference sample weight A. A digital display type counting scale is characterized in that when W<A, the calculation (A-W)/U is performed, and the result of this calculation is displayed on the display section. 2. It has a weight converter that converts the weight of the object to be measured on the weighing pan into an analog voltage, and an analog-digital converter that converts the analog voltage output from the weight converter into a digital signal and outputs it as weight data. The counting scale is provided with a processing device and a display section, and when an operator places a sample on the weighing pan and inputs the number N of the same samples from the operation section, the processing device outputs an output from the analog-to-digital converter. W/N is calculated based on the weight data W and the number N of the samples, thereby calculating the unit weight U of the sample, and comparing the W with the reference sample weight A, and determining that W<A. In this case, the operation (A-W)/U is performed, and the result of this calculation is displayed on the display section _.
When the sample is added, the weight data W ₁ output from the analog-to-digital converter is compared with the reference sample weight A, and if W ₁ <A, (A-W ₁ )/
A digital display type counting scale, characterized in that a calculation U is performed and the result of the calculation is displayed on the display section.