JPS63307320A - Switching device for measurement range of scale - Google Patents

Abstract

PURPOSE:To speed up weighing operation even if a maximum weighing output increases by controlling the span quantity of a multi-range type scale using a double integration type A/D converter when a maximum weighing output mode is switched to a constant value. CONSTITUTION:The analog weight value of an article which is obtained by a load cell 1, etc., is converted by the double integration type A/D converter 3 into a digital value and the weight is displayed 5 through a control part 4 provided with a scale switching key 6. This converter 3 integrates the input signal with a reference period first and then with a reference voltage having the opposite polarity in the latter half period. Then the integrated voltage value of the former half period is proportional to the input signal and the integration time of the latter half period is also proportional to the input signal value. Here, spans are set to respective maximum weighing outputs and an unknown input integration time which is in inverse proportional to the size of a current range is stored in the memory of the control part 4. Then, a range is set with a key 6, and the control part 4 controls the reference voltage integration time inverted in polarity after the unknown input integration time so that the span value of the scale in each range is constant.

Description

[Detailed description of the invention] (Industrial application field) The present invention relates to a measurement range switching device for a scale.

(Prior Art) Scales are often used in which the weight of an item as an analog value obtained by a load cell or the like is converted into a digital value by an A/D converter, and the digital value is input to a control unit to display the weight.

A double integral type A/D converter is known as an A/D converter used in this type of scale. This double-integration type A/D converter first integrates a human input signal for a reference period Ts in an integration circuit,
Subsequently, the integrating circuit is switched to a reference voltage with a polarity opposite to that of the human input signal, and this integrated value is returned to zero in a period T. Since the integrated voltage value in the first half of the integrating circuit is proportional to the input signal, the backward integration time T in the second half is also proportional to the input signal value, and A/D conversion is performed by counting clock pulses during this period.

By the way, a multi-range system has been developed that uses such a double integral type A/D converter to switch the measurement range of the scale to a plurality of scales.

FIG. 4 is a diagram illustrating the characteristics of double integration in a multi-range scale. In the figure, ■ is no load, ■ is maximum weighing 30
kg, ■ means maximum weighing 60 kg, ■ means maximum weighing 150 kg.
, and the unknown input integration time T is constant. And, (2) for the no-load output time z1, the count value Z of clock pulses is set to 2000.

For the time W of load output of 030kg, the count value is 17000.
Set to .

For the time W2 of load output of 060kg, the count value is 32000.
Set to .

At the time W3 of the maximum weighing output of 0150 kg, the count value is 77.
Set to 000. At this time, (1) The span value when used as a scale with a maximum weighing capacity of 30 kg is W + , Zr = 15000, (2) The span value when used as a scale with a maximum weighing capacity of 60 kg is W2 ZI = 30000, (3 ) The span value when used as a scale with a maximum weighing capacity of 150 kg is Ws Z+ = 75000, and these span values are the resolution of each scale.

Therefore, when using a scale with a resolution of 1/3000, (1) For a scale with a maximum weighing capacity of 30 kg, 5 counts is 10 g.
(2) For a scale with a maximum weighing capacity of 60 kg, 10 counts is 20
(3) For a scale with a maximum weighing capacity of 150 kg, 25 counts is 5
Set it to 0g, and process it in the control unit as follows. That is, 2g is constant for each measurement range per count.

(Problem to be solved by the invention) As described above, in a multi-range scale using a load cell with a maximum weighing capacity of 300 kg, the maximum weighing capacity is 30 kg.
A scale with a maximum weight of 150 kg can have a higher output than a scale with a maximum weight of 150 kg, but because the resolution is set to focus on a 30 kg load (lower load), the maximum weight is 150 kg. The problem with this scale is that it takes a long time for A/D conversion, and with a multi-range scale, it is not possible to speed up weighing.

Therefore, the present invention provides a measuring range switching device for a scale that solves the problems of the prior art.

(Means for Solving the Problems) The present invention is equipped with a means for switching and setting a weight measurement range in multiple stages, and a double integral type A/D converter for converting an analog value of weight into a digital value. In the scale used, the unknown input integration time of the double integration type A/D converter is reduced in inverse proportion to the size of the measurement range that has been switched, and the reference voltage integration time with reversed polarity after the unknown input integration time is The present invention is characterized in that a control means is provided for controlling the span value (resolution) of the scale to be constant at each switching stage of the measurement range.

(Function) In a multi-range scale using a double integral type A/D converter, the present invention provides that the unknown input integration time of the double integral type A/D converter is inversely proportional to the size of the measurement range. The reference voltage integration time, whose polarity is reversed after the unknown input integration time, is controlled so that the span value (resolution) of the scale is constant at each switching stage of the measurement range. Even when switching, high-speed weighing processing can be performed.

(Example) Hereinafter, an example of the present invention will be described with reference to the drawings. Third
The figure is a double integral characteristic diagram explaining the present invention in detail.

The basic principle of the present invention is to perform control such that the unknown input integration time is changed in accordance with the maximum weighing weight and the output (span value) is kept constant. In the figure, ■ No-load output time Z1 is the clock pulse count value 20
Set to 00.

■For the load output time Wl for the maximum weight of 30kg, the count value is 1.
7000.

Therefore, the span value when used as a scale with a maximum weighing capacity of 30 kg is W + Zt =
It becomes 15,000.

Next, when the scale is used at the maximum weighing output of 60 kg, the unknown manual integration time T2 is set to 1/2 of T. Here, ■ and ■ are the characteristics when the no-load output 22' is 1/2 of 21 when used with a load of 060 kg, and the count value is 1000.

The time W2' for the maximum weighing output of 060 kg is W2'
Control is performed by the control unit so that Z2' = 15000, that is, the count value is the same as the maximum weighing output of 30 kg.

Therefore, the time required for A/D conversion is T2 + w2
'=(T+/2)+W2', which is shorter than in the case of the maximum weighing output of 30 kg.

Similarly, when using a scale with a maximum weighing output of 150 kg, the unknown manual integration time is T3 = (115)T.

By selecting this, the time required for A/D conversion is shortened.

In the present invention, the following processing is performed with 5 counts as 1 digit.

(1) In the case of the maximum weighing output of 30 kg, 5 counts equals 1 digit of 10 g.

(2) In the case of the maximum weighing output of 60 kg, 5 counts = 1 digit and 20 g.

(3) In the case of the maximum weighing output of 150 kg, 5 counts equals 1 digit of 50 g.

FIG. 1 is a block diagram showing a schematic configuration of the present invention.

In the figure, 1 is a load cell, 2 is an amplifier, and 3 is an A/D
Converter, 4 is a control unit composed of a CPU with built-in memory, 5 is a display unit, and 6 is a scale switching key.

When using the scale, first set it to the maximum weighing output of 30 kg, take the span, and store the unknown input integration time TI at that time in the memory of the control section. Similarly, unknown input integration time T for 60 kg maximum weighing output and 150 kg maximum weighing output
2. T3, respectively T 2 = (1/2) T
I, Ts = (1/5)T, and store it in memory.

Next, the function of the scale switching key 6 will be explained. Each time the scale switching key is pressed, the load output mode (measurement range) of the scale is switched. For example, when using the maximum weighing output of 30 kg, the unknown input integration time T is read out from the memory and set as the control signal Ti, but if you press the scale switch key at this time, the scale is set to the maximum weighing output mode of 60 kg, and as the integration time of unknown input, T2 is read from the memory and the control signal Ti is determined.

Also, if you press the scale switch key when the scale is displayed, the load output mode (measurement range) of the scale will change from 30kg to 60kg to
The weight is sequentially switched from 150 kg to 30 kg, A/D conversion is controlled at each integration time, and the read value is set as the zero point.

FIG. 2 is a flowchart showing the processing procedure of the present invention. Next, this flowchart will be explained.

(1) Turn on the scale switching key in step S1, confirm that zero is displayed in step S2, and then
Check whether the maximum weighing output mode is 30 kg. If the determination at this time is YES, in step SA, the non-input integration time T2 of the maximum weighing output of 60 kg is set as the control signal Ti. This is because, as described above, when the scale switching key is pressed, the 60 kg maximum weighing output mode is set as the next mode after the 30 kg maximum weighing output. Next, jump to step S8 and proceed to step S. Step S11 sets the non-input integration reference time using the control signal Ti to control the A/D converter, and in step S11 the A/D converted value at that time is set as the zero point.

(2) If the determination is No in the process of step S3, it is checked in step S4 whether the maximum weighing output mode when the scale switching key is pressed is 60 kg, and if the determination is YES, in step S9 Maximum weighing output 150
The unmanned integration time T3 of kg is set as the control signal Ti.

In this case as well, the order of operation of the scale switching key is defined so that the 150 kgfi high weighing output is selected as the next mode after the 60 kg maximum weighing output.

Thereafter, in the same manner, the A/D converter is controlled by the control signal Ti through the processing of steps S1°+S11, and the A/D converted value is set as the zero point.

(3) If the determination in step S4 is No, it means that the scale changeover switch was pressed when the maximum weighing output was 150 kg, so step S is performed.

The integration time T1 of the maximum weighing output of 30 kg, which is specified as the following order, is set as the control signal Ti, jumps to step S6, and the same goes to step S1°+Sll.
Execute the process.

In the above example, we have explained a multi-range scale that switches between the maximum weighing output modes of 30kg, 60kg, and 150kg, but the maximum weighing output can be set to any value depending on the maximum weighing capacity of the load cell, and the number of switching stages is also 3 stages. It can be determined as appropriate without being limited to.

Although the gist of the present invention has been described above with reference to specific embodiments thereof, it is clear that various modifications or modifications of the present invention based on what has been described above are possible.

(Effect of the invention) As explained above, according to the present invention, the double integral type A
Multi-range scales using /D converters are controlled so that the span value remains constant when switching the maximum weighing output mode (measuring range), so even if the maximum weighing output increases. Weighing can be done faster.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing a schematic configuration of the present invention, FIG. 2 is a flowchart, FIG. 3 is an explanatory diagram of the present invention, and FIG. 4 is an explanatory diagram of a conventional example. 1...Load cell, 2...Amplifier, 3...-A/D
Converter, 4... Control unit, 5... Display unit, 6... Scale switching key.

Claims (1)

[Claims] In a scale that is equipped with a means for switching and setting a weight measurement range into multiple steps and using a double integral type A/D converter that converts an analog value of weight into a digital value, the size of the measurement range that has been switched and set. The unknown input integration time of the double-integration type A/D converter is reduced in inverse proportion to ) is provided with a control means for controlling the range to be constant.