PL151623B1 - ULTRASONIC SIGNAL PATH MEASUREMENT SYSTEM IN GAS ENVIRONMENT - Google Patents

Description

PATENT DESCRIPTION

151 623

REPUBLIC

POLAND

OFFICE

PATENT

RP

Patent Additional Patent No. --- Pending: 86 03 25 (P. 258631)

Preference Int. Cl.® G01F 23/28

Application announced: 87 12 14

Patent description published: 1991 03 29

Creators of the invention: Antoni Rosseger, Zbigniew Borczyk, Jan Blach

Entitled by the patent: Central Research and Design Center of Opencast Mining Poltegor ", Wrocław (Poland)

ULTRASONIC SIGNAL PATH MEASUREMENT SYSTEM IN GAS ENVIRONMENT

The subject of the invention is a system for measuring the ultrasonic signal path in a gaseous environment for measuring the volumetric efficiency of belt conveyors.

Polish patent specification No. 68 594 discloses an ultrasonic device for measuring the volumetric capacity of belt conveyors, equipped with transmitting and receiving transducers and placed above the conveyor belt at a constant height. The input of the transmitting converter is connected to the output of the surge generator connected in turn to the output of the synchronization circuit. The output of the receiving transducer is connected to the timer via a forming system. The timer is further connected to an output of the synchronization circuit and to an output of the belt speed sensor.

A transmitting transducer, driven by a percussion generator and a controlled synchronization system, generates short-term ultrasonic pulses and sends them towards the conveyor belt with the excavated material. After bouncing off the excavated material, these pulses reach the receiving converter, where they are converted into electrical signals and then amplified in the forming system. These pulses mark the time of receiving the reflected wave pulses in the time meter, after prior marking with a signal from the synchronization system of the time of sending the ultrasonic wave pulses. The height of the spoil stream, and hence the spoil cross-section, is determined in the time meter on the basis of the difference in transit time of the ultrasonic pulse for the empty belt and for the belt filled with the spoil. In this system, it is assumed that the speed of the ultrasonic wave is constant, and its value is adjusted periodically by resetting the system, 00 due to the operation of the device in industrial conditions, it may not be performed very often. The disadvantage of such a solution is that the velocity of the ultrasonic wave varies between the zeroing periods, and this causes an increase in the measurement error.

The Polish patent specification No. 134 754 discloses a method and a system for compensating the influence of temperature on the measurement of the ultrasonic signal path. This method consists in measuring the tempera151 623

151 623 tare of the environment and generating the signal, comparing it to the desired value and converting it into an electrical signal, which adds up to the electrical signal corresponding to the average velocity of the ultrasonic wave for the desired temperature and converts it into a current signal, integrated during the ultrasonic signal's passage along the measured path . The system implementing this method is equipped with transmitting and receiving ultrasonic signal converters, connected to the pulse generator, with the input connected to the output of the belt speed sensor. In addition, the system has a temperature sensor located near the transducers and a temperature-to-electrical transducer with an output connected to the current transducer, and this in turn with the output of the average speed ultrasonic signal generator. The output of the current transducer is connected to the signal input of the integration circuit, in parallel with the output of the transition time measurement circuit. The output of the folding circuit is connected to the input of the meter. The above method eliminates the influence of only one of the external factors, namely the influence of the ambient temperature on the measurement of the ultrasonic signal path.

The invention relates to an ultrasonic signal path measurement system in a gaseous environment for measuring the volumetric efficiency of belt conveyors, equipped with a pulse generator connected to a transmitting and receiving ultrasonic transducer at a known height, including an ultrasonic signal transit time measurement member, a belt speed control member and processing and processing devices. result identification. The essence of the invention is that the pulse forming member is connected between the pulse generator and the pulse identification member, both of which are connected to the output of the belt speed control member. One output of the pulse identification segment is connected to the time measurement segment, and the other to the pulse type control module, connected to the averaging segment of their values. The output of the time measuring unit is connected to the pulse type control element and at the same time to the ultrasonic pulse path value calculating unit, to the output of which further calculation and result identification elements are connected. The averaging stage is connected with the signal output and the control output with the corresponding inputs of the transitional time memory segment of the ultrasonic impulse reflected from the empty tape, the output of which is connected with the input of the path value calculation segment, connected with the control inputs to the pulse type identification segment and the transition time value averaging segment.

The system according to the invention allows for complete independence of measurements from changes in the velocity of the ultrasonic wave in the air, resulting from changes in air parameters. It was obtained thanks to the systematic correction of the value of T _z , i.e. the measurement of the time of the ultrasonic signal reflected from the empty strip, which occurs every time there is no material on the belt. The time T _z at a constant height h _{from the} built-in transducers contains information about the current velocity of the ultrasonic wave, which is a new reference value for further measurements. The realized value of the spoil height h _u , which is the basis for further calculations, is based on the relation:

where: h _u - height of the excavated material h _z - height of the transducers installation

Τ _χ - transit time of the ultrasonic impulse reflected from the excavated material

T _z - transit time of the ultrasonic impulse reflected from the blank tape.

The subject of the invention is illustrated in an embodiment in the drawing, in which the block diagram of the system is shown.

An exemplary system is designed to measure the volumetric efficiency of a belt conveyor. The assembly 1 of transducers composed of the transducer transmitting and receiving is positioned at a constant height h _of the conveyor belt TP. The set 1 of the transducers is connected to the generator 2 of pulses containing the signal of the resonant frequency of the transmitting and receiving transducers. The TP belt speed control unit 3 is connected

151 623 with controlling inputs of pulse forming element 4 and controlling inputs of pulse identification element 5. The pulse shaping unit 4 is connected to a pulse generator 2. The outputs of the transmit pulses N are connected to the inputs of the pulse identification element 5. One output of the pulse identification stage 5 is connected to the signal input of the time measurement unit 6 Τ _{χ of the} transition of the ultrasonic signal reflected from the spoil, and the other output of the stage 5 is connected to the control input of the pulse type control stage 7. Output member 6 timing _Τ χ is connected to the signal input control member 7 type impulses which signal output is connected to the signal input member 8 averaging pulses. The same output timing member 6 _Τ χ is connected to the signal input member 9 of calculating the height h ^ ore U TP on the tape carrier. The segment 9 is connected to the control outputs of the segment 7, the segment 8 and the time memory segment 10 _{of the} transition of the ultrasonic impulse reflected from the empty TP band. The component 9 for calculating the height h ^ of the output U has a signal output connected to the input of the component 11 of the calculation of the instant Q cross-section of the output U. The output of the component 11 is connected to the input of the averaging component 12 of the cross-section Q value and the input of the component 13 of summing the instantaneous values Q. transmitting N of the forming unit 4 is further connected to the control inputs of the pulse type control unit 7 and the Q section sum of the instantaneous values. The control output of the section 7 is connected to the control input of the unit 8, whose control output and signal output are connected to the corresponding inputs of the unit 10 time memory T. The averaging segment 12 of the value of the section Q of the output U is connected with the index 14 of this value, and the term 13 of summing the instantaneous values of the section Q of the output U is connected with the numerator 15.

The measurement of the volumetric capacity of the conveyor belt is carried out in an exemplary arrangement as follows. In the generator 2, pulses are generated containing a signal at the resonant frequency of the transducers, which activate the transmitting transducer, which causes an ultrasonic impulse to be sent towards the TP belt. This impulse, after bouncing off the surface of the output U, reaches the receiving transducer, which converts it into an electrical signal. Pulse generation is triggered by the forming member 4 while the TP belt is moving at rated speed, which is ensured by giving the forming member 4 a signal from the TP conveyor belt speed control member 3. In the Pulse forming member 4 based on the signals received from the set 1 of the converters through the generator 2, transmit N, receive 01 and receive pulses O1 are standardized, additionally received when there is no output U on the TP band, i.e. when it is empty.

In the pulse identification element 5, the time of sending 1 return of one pulse is compared, which contains information about the path traveled by the pulse at a constant ultrasonic wave speed. Based on this time, the constant height h _{2 of the} set of 1 transducers and the ultrasonic wave velocity obtained on the basis of time Τ _χ from the previous measurement in system 9, the height h _{of the} spoil U on the TP belt is calculated. If, during the measurement of efficiency, an empty TP tape moves under the set of 1 transducers, the receiving transducer receives a reflected pulse and an additional reflected pulse, which activates the operation of the system 7, which receives the time measurement signal from the system 6 and checks the number of these subsequent measurements, and hence the speed of the ultrasonic signal The measurement is based on the time that elapses from the return of one pulse, while the average value from several measurement cycles is taken to calculate the speed, which is performed by the term 8 · The 11 term is used to determine the cross-section Q of the output U for a given height h ^ obtained from the term 9 · The instantaneous value of the efficiency Q is averaged over the term 12 and exposed to the index 14 ·

The system 13 with a cycle of transmitting pulses generates pulses corresponding to unit sizes of the transported output. These pulses are summed up in an electromechanical counter 15.

Claims (1)

Patent claim Ultrasonic signal path measurement system in a gaseous environment for measuring the volumetric efficiency of belt conveyors, equipped with a Pulse generator connected to a transmitting and receiving ultrasonic transducer, located at a known height, za4 151 623 an insertion of the ultrasonic signal transition time measurement member, the belt speed control member and the result processing and indication device, characterized in that the pulse forming member (4) is connected between the pulse generator (2) and the pulse identification member (5), both these elements (4, 5) are connected to the output of the belt speed control (TP) stage (3), while one output of the pulse identification stage (5) is connected to the time measurement stage (6) and the other to the type control stage (7) pulses, connected to the element (8) averaging their values, and the output of the time measurement unit (6) is connected to the pulse type control unit (7) and at the same time to the ultrasonic pulse path value calculation unit (9), to the output of which further stages are connected (11, 12, 13, 14, 15) for calculation and indication of the result, while the averaging term (8) is connected to the signal output and the control output with the corresponding inputs of the time memory (10) ( T ₂ ) transition of the ultrasonic impulse reflected from the blank tape (TP), the output of which is connected to the input of the path calculation stage (9) connected to the control inputs with the pulse type identification stage (7) and the transition time averaging stage (8). Department of Publishing of the UP RP. Circulation 100 copies Price: PLN 3,000