JPS6339613Y2 - - Google Patents

Description

[Detailed Description of the Invention] The present invention relates to a tare erase circuit in an electronic weighing machine using a bridge balance type load cell as a load converter.

Figure 1 shows the load conversion section of a conventional electronic weighing machine, in which 1 is a bridge balance type load cell (hereinafter referred to as load cell), and four active gauges 2a, 2b, 2c, 2d with a specific resistance value R are R+ΔR, R-, respectively, due to the action of the tare load.
They are attached to blocks so that they change as ΔR, R+ΔR, and R-ΔR, and are housed in one housing. 3 is an excitation power source for the load cell 1, 4 is a preamplifier that amplifies the output of the load cell 1, 5 is a differential amplifier that remotely senses the excitation voltage applied to the load cell 1, and 6 is the preamplifier 4 using the output of the differential amplifier 5 as a reference voltage. A double integral type analog-to-digital converter converts the output to digital, and V ⁺ and V ^- represent the polarities of the connection point between the excitation power source 3 and the load cell 1, which are disposed outside the load cell 1 case. similarly
In ⁺ and In ^- represent the polarities of the connection lines between the preamplifier 4 and the load cell 1, and Vsen ⁺ and Vsen ^- represent the polarities of the connection lines between the differential amplifier 5 and the load cell 1. Reference numerals 7 and 7' denote tare erasing resistors having a resistance value corresponding to the amount of tare.Resistor 7 or 7' is inserted into the circuit, and FIG. 1 shows the inserted state of resistor 7.

Also, the arrow XX side represents the weighing device main body side,
Weighing device body and load cell 1 as a load converter
For example, in a truck scale, the load cell 1 is installed outdoors, and the weighing device itself is installed indoors. Since the load cell 1 is disposed in such a state, the load cell 1 is particularly subjected to temperature changes. Note that the load cell 1 is temperature-compensated so that the relationship between load and output voltage does not change even if the resistance value of each gauge changes due to temperature change.

The tare eraser circuit configured in this manner has the following problems. The resistance value of resistor 7 is
R _T , the amount of tare erased by the resistor 7 is determined by the ratio of the specific resistance value R of each gauge 2 a to 2 b of the load cell 1 to R _T . Therefore, when the specific resistance value R of the gauge of the load cell 1 changes due to a temperature change, the amount of tare erased by the resistor 7 changes, and the zero point of the scale changes.

Additionally, if load cell 1 is subjected to a load exceeding its rating, its reliability will be significantly impaired, so an overscale detection circuit is implemented to monitor the output voltage of preamplifier 4 and detect if load cell 1 exceeds its rating. [not shown], but in this case, in the conventional tare erasing circuit shown in FIG. 1, it is necessary to add a switch or the like to turn off the tare erasing resistor 7.

The present invention has been developed in view of the above-mentioned problems, and provides an apparatus in which the amount of tare erased is completely unaffected by the resistance of the gauges 2a to 2d, and moreover, an overscale detection circuit can be easily realized.

An embodiment of the present invention will be described below with reference to FIG. Components having the same functions as those in FIG. 1 are designated by the same reference numerals and their explanations will be omitted.

8 is a resistor according to the tare amount, 9 is a preamplifier 4
For example, an adder corrects the output using the output voltage of the differential amplifier 5, and a voltage corresponding to the net load value obtained by subtracting the tare amount is generated at the output of the adder 9. Note that the output of the preamplifier 4 has a positive polarity, and the output of the differential amplifier 5 has a negative polarity.

Reference numeral 10 denotes a comparator as an overscale detection circuit, and a preamplifier 4 output voltage corresponding to the rating of the load cell 1, for example, is applied to a terminal 11.

Because of this configuration, even if a change in specific resistance occurs in the gauges 2a to 2d of the load cell 1, the amount of tare compensation by the resistor 8 applied to the unknown voltage input to the analog-to-digital converter 6 is Since there is no change, accurate tare erasure can be performed, and the overscale detection circuit does not require a switch to turn off the tare compensation resistor as in the conventional case, and the circuit configuration can be simplified.

Next, it is established that the preamplifier 4 output voltage γ with respect to the rated load of the load cell 1 is constant. If the amplification degree of preamplifier 4 is K, and the unit of V ⁺ and V ^- is [V], then γ = (V ⁺ −V ^- )・α・K [mV] = K・α/1000・(V ⁺ −V ^- ) [V]. Here, since K.α.V ⁺ .V ^- can be kept constant, the preamplifier 4 output can be kept constant for the rated load, and therefore the voltage applied to the terminal 11 of the comparator 10 can be kept constant. Overscale can be detected by determining it in accordance with the preamplifier 4 output voltage at the rated load.

As explained above, according to the tare eraser circuit of the present invention, the amount of tare eraser is completely unaffected by the bridge resistance value of the load cell, and accurate tare compensation can be performed.Moreover, the overscale detection circuit configuration Since it is possible to simplify the process, it is possible to improve the reliability of the weighing device.

[Brief explanation of the drawing]

FIG. 1 is an explanatory diagram of a conventional tare eraser circuit, and FIG. 2 is a configuration diagram of an embodiment of the present invention. 1... Bridge balance type load cell, 3...
Excitation power supply, 5...differential amplifier, 6...analog
Digital converter, 8... tare compensation resistor [voltage dividing means], 9... adder [calculating means].

Claims (1)

[Scope of utility model registration request] A bridge balance type load cell is used as a load converter, and an analog-to-digital converter uses a voltage obtained by remotely sensing the excitation voltage of the load cell as a reference voltage for digital conversion via a differential amplifier, and converts the output voltage of the load cell via a preamplifier. In an electronic weighing machine configured to digitally convert a voltage, the voltage dividing means obtains a voltage according to a tare amount from the output of the differential amplifier, and the output voltage of the preamplifier is compensated for the tare by the output voltage of the voltage dividing means. and arithmetic means for applying an output voltage to an unknown input of the analog-to-digital converter.