JPH0312245B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an electronic digital display scale in which each weight value in a weighing range is set using a reference constant having a fraction.

Conventionally, electronic digital display scales convert the weight of the object to be weighed into an analog electrical signal using a weight detection means such as a load cell or force balance, and convert this signal into a digital signal using an AD converter to perform counting operations. It has a digital display, and its feature is that it has higher resolution than other scales. In this scale, even in a no-load state where the weight of the object to be measured does not act, the weight of the weighing pan and other constituent members acts on the weight detection means, so the weight detection means detects the weight of these components. Therefore, the AD converter constantly outputs a digital signal, and it is necessary to set this signal as the zero point of the scale. here,
Let the count value output from the AD converter be y,
If the unit weight digit is displayed using the a count value, and the weight at that time is x, and the count of b is output when the weighing value is "0", then y=ax+b...Equation (1) Expressed as a linear relationship. From this, the effective range of the scale is x = y-b/a...Formula (2), so for example, at 25,000 counts, the weighing range is 5.
If you try to configure a kg scale, it will be 5 counts per 1 g, and in equation (2), when x = 5000, y - b
It is necessary to finely adjust the amplification degree of the analog signal of the weight detection means so that the weight signal of =25000 counts is accurately output from the AD converter.

By the way, as mentioned above, the weight detection means includes
Since it takes time for the scale to reach a stable state due to the weight of the weighing pan and other components, initial fluctuations in the operation of the scale, temperature changes, etc., the above-mentioned (2) There were problems such as it was extremely troublesome to establish the formula strictly and it took time to adjust it.

This invention was made in consideration of the above circumstances, and is based on digital signals and weighing ranges at two points: when a standard weight is applied to the weighing pan and when the weight of the object to be weighed is "0". By automatically calculating the constant, you can omit the work of fine-tuning the amplification degree of the weight detection means, and the minimum display unit suitable for the calculated reference constant a can be automatically set. Even when increasing the number of counts to improve resolution, operations such as setting the reference constant a are easy, and even if the characteristics of the weight detection means change, there is no need to change the main electrical circuits below the AD converter. The purpose is to provide a type digital display scale.

The present invention will be described below based on embodiments shown in the drawings.

In Fig. 1, the reference numeral 1 indicates a weighing pan, and the reference numeral 2 indicates an object to be weighed placed on the weighing pan 1. It is detected by a weight converter 3 such as a balance and transmitted to an AD converter 4 as an analog signal of an appropriate magnitude. This AD converter 4
is configured to convert the analog signal of the weight converter 3 into a digital signal and output it, and transmit the count number y to a central processing unit (hereinafter referred to as CPU) 5. The CPU 5 calculates the count number y of the AD converter 4 to obtain the weight x of the object to be weighed using the equation (2) above, displays this digitally on the display 6, and also displays the weight x of the object to be weighed using the display 6. In this case, the unit price is set using the operation section 7, the price is calculated, and the unit price, price, etc. are also digitally displayed on the display section 6.

Further, the CPU 5 or the operation unit 7 is provided with a zero point setter 8 for storing the count number b output from the AD converter 4 when the weighing plate 1 is in an unloaded state in the CPU 5 as the zero point of the scale. At the same time, when standard weight x ₀ is applied to weighing pan 1, AD
From the count number y ₀ output from the converter 4 and the count number b in the no-load state, a=y ₀ −b/x ₀ ......The CPU 5 calculates and stores the reference constant a according to equation (3). A constant setting device 9 is provided for setting the weight value of the weighing range based on the reference constant a.

Note that the CPU 5 corresponds to the first and second calculation means and storage means in the claims.

This will be explained below using an example. When the scale is placed in a no-load state, the weight of the weighing plate 1 acts on the weight converter 3, and an output appears on the AD converter 4. At this time
If the count number of the AD converter 4 is b=3456, this number is first stored in the CPU 5 by the operation unit 7 and the zero point setter 8, and then the display is started as zero.

Next, a standard weight of 5 kg is placed on the weighing plate 1. If the output count number of the AD converter 4 changes to 28765 due to the placement of this standard weight, the reference constant can be obtained from the above equation (3), and the operating section 7 and the constant setting device 9 Standard weight 500g according to the directive of
and the count number 28765 are input to the CPU 5, and the CPU 5 is made to perform the calculation of equation (3) using the pre-stored count number 3456 at no load.
That is, a= _y0 -b/ _x0 =28765-3456/5000=5.0618, and this a=5.0618 will be used as the reference constant from now on.
It is stored in the CPU 5 and used as a calculation standard.

Further, following the reference constant setting, the CPU 5 automatically sets the display unit and the weight value of the weighing range. Here, if the display unit (display resolution) of the scale is internal count number 4 or more,
If you select 1g, 2g, 5g, or 10g as the display unit, CPU 5 will, for example,
If it is determined that =5.0618>4, 1 g unit will be displayed for every count number of 5.0618. The maximum weighing range at this time is, for example, the maximum output count number of the AD converter 4.
If it is 30000, the CPU 5 calculates x=y-b/a=30000-3456/5.0618=5243.9 using equation (2), and it becomes possible to weigh within the range of 5243 g or less. In the event that the weight of the object to be weighed exceeds 5243 g, the CPU 5 determines whether it exceeds the weighing range (overflow) and causes the display 6 to display the result.

On the other hand, in FIG. 1, the sensitivity or amplification degree of the weight converter 3 is changed, or
By exchanging , the numerical condition becomes y ₀ = 16850,
The case where b=987 and x ₀ =15 kg will be explained. In this case as well, the CPU 5 sets the reference constant by the same operation as in the previous example. That is, a= _y0 -b/ _x0 =16850-987/15000=1.057333 is calculated using equation (3). This a is smaller than the internal count number 4, so it cannot be displayed in units of 1g, and the 2g, 5g,
The minimum display unit of 5g is set by determining 1.057533×2<4<1.057533×5 from among the 10g display units, and the weighing range is calculated by CPU5 as x=30000−987/1.0575333=27434.5g. Automatically set.

That is, in the present invention, even if the conditions of the weight converter 3 are arbitrarily changed, there is no need for troublesome adjustment work such as adjusting the amplification degree of the weight detection means, and the condition of the AD converter 4 and below can be changed. The minimum display unit and weighing range can be automatically set without changing the main electrical circuit.

In the above-mentioned embodiment, the reference constant was obtained using equation (3) and the subsequent weight detection was performed using this a, but the reciprocal of a, the value obtained by dividing a by another coefficient, etc. The CPU 5 may be made to detect the weight as a reference.

As is clear from the above explanation, the present invention sets a reference constant based on the output count of the AD converter under no load, the output count of the AD converter when a standard weight is applied, and the standard weight. However, since the weighing range and minimum display unit are determined by this reference constant, the output count number of the AD converter can be made to correspond to the standard weight by adjusting the amplification degree of the weight detection means. Such troublesome adjustment work can be omitted, and the minimum display unit suitable for the set reference constant can be automatically set. In addition, even when the resolution is increased by increasing the output count number of the AD converter, operations such as setting reference constants are easy, and even if the characteristics of the weight detection means change, the main electrical circuits below the AD converter can be easily operated. It has the advantage that it can be shared and the measurement range can be widened.

[Brief explanation of drawings]

FIG. 1 is a block diagram illustrating an embodiment of the structure of the present invention, and FIG. 2 is a graph showing the relationship between electrical characteristics. 3... Weight converter, 4... AD converter, 5... Central processing unit (CPU), 7... Operation unit, 8... Zero point setter,
9...Reference constant setter.

Claims (1)

[Claims] 1. A weight converter that converts the weight of an object to be measured into an electrical signal, an AD converter that converts the output signal of the weight converter into a digital signal, and an output of the AD converter when no load is applied. a zero point setter for taking in the count b; a reference constant setter for taking in the output count y ₀ of the AD converter when standard weight x ₀ is measured as the object to be measured; and the output count b, y ₀ . and a first calculating means for calculating a reference constant a from the standard weight x ₀ using the formula a = (y ₀ - b)/x ₀ , a storage means for storing the calculated reference constant a, and a stored reference constant. a setting means for setting the minimum display unit based on a, a second calculation means for calculating the weight of the object to be weighed from the stored reference constant a and the output of the AD converter at the time of weighing the object; an electronic digital display scale, comprising display means for displaying in the minimum display unit set by the setting means.