CS258753B1 - Device for measuring scanned physical variable's magnitude change in time - Google Patents

Abstract

Wiring is part of the measuring technology industry and relates to a size change measuring device sensed physical quantities over time consisting of a storage bin, a returnable binary counter, control sequence logic circuit and an evaluation device, the essence of which is that the control sequential logic circuit it is connected to a pulse generator, a switch, a returnable binary counter and storage device to which the evaluation device is connected, wherein the switch is coupled to a returnable switch a binary counter that is connected to a storage device. To connect a returnable binary counter and the accumulator is classified as a logical combination circuit. A converter is connected to the switch measured quantities. It is possible use, for example, to determine instantaneous asynchronous motor power measurement slip.

Description

BACKGROUND OF THE INVENTION The present invention relates to an apparatus for measuring the magnitude of a sensed physical quantity over time, based on the principle of converting a sensed physical quantity into electrical pulses, the frequency of which is proportional to the magnitude of the sensed physical quantity.

So far, to determine the magnitude of the physical quantity over time, a device consisting of an electrical converter of physical quantity into digital form, electronic accumulators for storing the captured quantity, an electronic digital adder or subtractor, an electronic control sequence circuit and an evaluation device is used. The disadvantage of this device is its complexity, which results in its high price.

In essence, the present invention is an apparatus for measuring the magnitude of the physical quantity over time, consisting of a storage, a return binary counter, a control sequential logic circuit, and an evaluation device, and having the first output connected to the output of the converter. a switch input, wherein the second and third inputs of the switch are connected to the first and second outputs of the control sequential logic circuit connected to the pulse generator and the outputs of the switch are connected to the first and second inputs of the binary counter counter; circuit, whose fourth output is connected to the storage input of the storage, which is preceded by a logic combinational circuit, to whose binary inputs the outputs of the return binary counter are connected and its outputs are connected to the binary input of the accumulator connected to the binary inputs of the evaluation device. ·

The higher effect of the device according to the invention lies in the simplicity and low cost of the device.

An example of a specific embodiment of the device according to the invention is shown schematically in the attached drawing in the form of an electrical block diagram.

The device according to the invention consists of a converter 1 provided with an input 11 of the measured quantity.

For converter and is ranked Switch 2, wherein the electrical output 12 of the converter 2 is connected to the first 'input 21 switches 2 · The second input 22 and a third input 23 switches 2 are connected to the outputs 31, 32 control sequential logic circuit 2 »linked ^to it pulse generator output 41 · Downstream of switch 2, a return binary counter 2 is connected to the first input 51 and second input 52 of which the outputs 24, 25 of switch 2 are connected.

The third output 33 of the control sequential logic circuit 2 is connected to the third input 53 of the return binary counter 2. which is also connected to the fourth output 34 of the control sequential logic circuit 3. The outputs from the storage 2 are connected to the binary inputs 81 of the evaluation device 2.

Before the start of the measuring cycle, the resetting binary counter 5 and the accumulator 7 are reset to zero. The frequency converter 2 generates pulses whose frequency is proportional to the sensed value, and these pulses input through the first input 21 to the switch 2. The switch 2 is switched so that the pulses applied thereto do not exit. The measurement cycle begins by controlling the sequential control logic circuit 2, controlled by regular pulses coming to the control sequential logic circuit 2 by input 30 from the pulse generator output 41, to send an opening signal to the second input 22 of switch 2. the first input 2l of the switch 2 from the electrical output 12 of the converter 1f to pass to the first output 24 of the switch 2 ' After a certain period of time, the control sequential logic circuit 3 cancels the opening signal applied to the second input 22 of the switch 2 and sends the opening signal to the third input 23 of the switch 2. to the second output 25 of the switch 2, which is connected to the second input 52 of the return binary counter 2 for counting the return counter 5. As a result, the return binary counter 2 subtracts the impulses supplied from the original counter state. This phase of measurement is terminated by canceling the opening pulse that is applied to the third input 23 of the switch 2. from the second output 32 of the control sequential logic circuit 2. The reading interval is as long as the reading interval. The status of the return binary counter 5 is indicated in binary form at its outputs, which are connected to the binary inputs 61 of the logic combination circuit 6, which determines whether the measurement result is positive or negative, according to the state of the highest bit of the return binary counter. If the result is negative, the logic combination circuit 6 performs a logic inversion of the individual signals on its binary inputs 61 from the return binary counter 5 at its outputs connected to the binary inputs 71 of the storage 2. the circuit 2 '' through its fourth output 34 connected to the write input 72 of the storage ^; 2 The pulse for writing the resulting modified binary state fed to the accumulator 7 via the binary inputs 71. The accumulator 7 stores the measured result information and passes it to the binary inputs 81 of the evaluation device 2 The last phase of the measuring cycle is resetting the return binary counter 5 a logic circuit 2 with an impulse, which, via its third output 33, sends to the third input 53 of a binary counter counter

2. The device is ready for further measurements.

The device can be used, for example, to determine the instantaneous power of an asynchronous motor by slip measurement.

Claims (1)

OBJECT OF THE INVENTION Apparatus for measuring the magnitude of a scanned physical quantity over time, consisting of a storage, a shaky binary counter, a control sequential logic circuit and an evaluation device, characterized in that a first switch input (21) is connected to the output (12) of the converter (1) (2), the first and second outputs (31, 32) of the control sequential logic circuit (3) connected to the pulse generator (4) and the outputs (2) being connected to the second input (22) and the third input (23) of the switch (2); 24, 25) of the switch (2) are connected to the first and second inputs (51, 52) of the return binary counter (5), to the third input (53) of which the third output (33) of the control sequential logic circuit (3) is connected. the fourth output (34) is connected to the write-in input (72) of the storage (7), which is preceded by a logic combination circuit (6), to whose binary inputs (61) the outputs of the return binary counter (5) and Its outputs are connected to the binary inputs (71) of the storage (7) connected to the binary inputs (81) of the evaluation device (8).