RU154872U1 - ULTRASONIC FLOW METER - Google Patents

Abstract

1. An ultrasonic flow meter containing a measuring chamber mounted in a fluid stream, N — pairs of input and output sensors mounted on the measuring chamber, an exciter, a first switching device connected to the sensors and the exciter and installed between the sensors and the exciter with the possibility of selective connection of the sensors with the pathogen, and the pathogen alternately excites each input and output sensor, a receiver connected to the first switching device, the first switching device, installed with the possibility of connecting each sensor to the receiver, and a second switching device connected to the exciter and the receiver, characterized in that the switching devices are made in the form of keys of a L-shaped structure, a matching resistance (Z1) is connected directly to the output of the exciter, directly to the input of the receiver included matching resistance (Z2), approximately equal to (Z1), the resistance of any key (Rcl) is much less than matching resistance (Z1, Z2), and matching resistance values do not exceed triple the resistance of the sensors according to the ratio Rcl << Z1≈Z2 <3 | Z of the sensor |, the first switching device is made in the form of 2N keys, the number of which is equal to the number of sensors and each key is connected in series with one sensor, all keys connected in series with the sensors ( connected) to one point, which is the connection point for two more keys of the second switching device, the first of which is connected to the output of the exciter with matching resistance (Z1), and the second to the input of the receiver with consent

Description

The utility model relates to ultrasonic flow meters that can be used to measure the volumetric flow rate of liquids, gases, gas-liquid mixtures, and liquids containing undissolved solid particles.

A device is known for passing ultrasonic frequency signals through a controlled medium in a pipeline, containing a source of ultrasonic frequency signals of at least “N” -controlled keys, at least “M” -the first ultrasonic piezoelectric transducers installed on a pipeline with a controlled medium and connected with their respective terminals to the corresponding conclusions of one of at least “Ν” - the corresponding controlled keys, “M” - the second ultrasonic piezoelectric transducer installed on a pipeline with a controlled environment and connected by their respective terminals to the corresponding second terminals of others of at least “N” - corresponding controlled keys, an amplifier, a control circuit connected by its respective outputs to the corresponding control inputs, at least “N” - controlled keys, and to the input of the ultrasonic frequency signal source, moreover, the device is equipped with an isolation circuit connected by its input to the output of the ultrasonic frequency signal source and output them to the respective first terminals, at least, «N» - driven keys and to the input of the amplifier (RF invention application №2012107407, G01F 1/66, 2012 YG).

The disadvantage of this device is a significant error in the measurement of flow. This disadvantage is caused by the difference in the group delay time (hereinafter referred to as the delay time) of the passage of signals along and against the flow of the controlled medium in the pipeline in the absence of movement of the controlled medium. The specified error is due to the fact that the output of the isolation circuit is directly connected to the input of the amplifier. The probe signal is large with respect to the received amplitude acts on the input of the amplifier and, therefore, causes its saturation. As a result, the non-linearity of the amplifier increases, which in turn leads to the non-identical state of the acoustic signal distribution of acoustic signals directed along and against the fluid flow, which means that the error in the flow measurement increases. In addition, the device does not provide means for matching the output impedance of the isolation circuit with the input impedance of ultrasonic piezoelectric transducers. The mismatch of the indicated resistances among themselves leads to a difference in the GVZ of the signals directed along and against the flow of the controlled medium, at least proportional to the difference in the resistances of the piezoelectric transducers. In addition, the mismatch of the output resistance of the isolation circuit and the input resistance of piezoelectric transducers leads to a decrease in the signal transmission coefficient from the isolation circuit to the flowmeter amplifier, and therefore to a deterioration of the signal-to-noise ratio at the amplifier output and an increase in at least a random component of the flow measurement error. The error in the formation of the GVZ signals along and against the flow of the controlled medium (when the medium is stationary) leads to an increase in the systematic component of the error in the measurement of the flow rate, which for time-pulse flow meters is directly proportional to the difference in the GVZ signals directed along and against the flow when the medium is stationary.

A known transmitting and receiving circuit for an ultrasonic flow meter containing at least two ultrasonic measuring transducers (TR1, TR2) installed for transmitting and receiving ultrasonic signals in opposite directions at the measuring section, a signal source for controlled generation of electrical signals for transmission to ultrasonic measuring transducers (TR1, TR2), the detection means for obtaining transmission time measurements necessary for calculating the flow rate to be measured will amplify having a first inverting input for connecting to one ultrasonic measuring transducer (TR1, TR2), a second non-inverting input for connecting to a signal source, an output for connecting with detection means, a feedback circuit (Z2) between the output and the first input, as well as switching means (S1, S2) for alternately functional connection of one of the ultrasonic measuring transducers (TR1, TR2) with the first input of the amplifier. In other embodiments of the circuit, the measuring transducer (TR1, TR2) is connected in series with one switching means (S1, S2), these series-connected measuring transducer and switching means (TR1, S1; TR2, S2) are connected in parallel; or a measuring transducer (TR1, TR2) is functionally connected to the first input of the amplifier and is connected between the first input of the amplifier and the reference voltage source; or a measuring transducer (TR1, TR2) is functionally connected to the first input of the amplifier and is connected between the first input of the amplifier and the reference voltage source. Each transducer (TR1, TR2) is connected in parallel with one switching means (S1, S2), these parallel connected measuring transducer and switching means (TR1, S1; TR2, S2) are connected in series. The circuit uses ultrasound with a frequency of 500 kHz - 2 MHz. The circuit uses a measuring tube with N-measuring transducers, where N> or = 2. (RF patent No. 2200938, G01F 1/66, 2003).

The disadvantage of the transmitting and receiving circuits for an ultrasonic flow meter is the significant difference between the GVZ signals directed along and against the flow of the controlled medium in the measuring section. The indicated difference in the GVZ is due to the fact that the measuring transducers are somehow included in the feedback circuit of the amplifier (receiver). The complex resistances of the transducers inevitably differ from each other. Therefore, the amplitude of the generated probing signals, which, depending on the switching circuit TR1 and TR2, is either proportional to or inversely proportional to the resistance of the converters, will inevitably be different for signals directed along and against the flow of the controlled medium. The difference in the amplitudes of the probing signals due to the non-ideality (presence of non-linearity) of the amplifier will lead to a difference in the delay times of the generated probing signals, and therefore to an increase in the zero offset of the flow meter and an increase in the error of flow measurement.

Closest to the technical nature of the claimed is an ultrasonic flow meter containing a measuring chamber mounted in a fluid stream, N - pairs of input and output sensors installed on the measuring chamber, a pathogen, a first switching device connected to the sensors and the pathogen and installed between the sensors and pathogen with the ability to selectively connect sensors to the pathogen, and the pathogen alternately excites each input and output sensor, the receiver connected from the first switching device, the first switching device mounted with the possibility of connecting each sensor to a receiver, and a second switching device coupled to the exciter and receiver. The measuring chamber is made in the form of a coupling. Switching devices are made in the form of multiplexers. In other embodiments: a second output sensor is connected to a second input sensor, a first driver is selectively connected to a second input sensor, and to a second output sensor, a first driver excites a second input sensor and a second output sensor; a second pathogen associated with the second input and output sensors; a second multiplexer connected to the second input and output sensors (RF patent No. 2449248, G01F 1/66, 2012).

The disadvantage of the scheme is the insufficiently high accuracy of the measurement due to the zero offset of the flow meter and a significant noise level. The indicated zero offset occurs due to the lack of means for aligning the output resistance of the pathogen and the input resistance of the receiver, which are connected alternately with the help of a second switching device to the sensors. The complex resistances of the sensors are not identical. By analyzing the signal passage from the pathogen output to the receiver input by means of the four-terminal theory, it can be shown that with a stationary controlled environment, the minimum difference in the delay times of the signals in and against the flow is achieved if the output resistance of the pathogen and the input resistance of the receiver are equal. The difference in the delay times for a stationary controlled environment determines the zero offset of the flowmeter, and, consequently, the measurement error of the controlled medium flow. Thus, the inequality of the output resistance of the pathogen and the input resistance of the receiver increases the error in measuring the flow rate of the controlled medium.

The problem solved by the utility model is to increase the accuracy of flow measurement, both by reducing the systematic component of the error (by significantly reducing the zero offset) and by reducing the random component of the error (i.e. by reducing the noise level).

The problem is solved in an ultrasonic flow meter containing a measuring chamber installed in a fluid stream, N-pairs of input and output sensors mounted on the measuring chamber, a pathogen, a first switching device connected to the sensors and the pathogen and installed between the sensors and the pathogen with the possibility of selective connection of sensors with the pathogen, and the pathogen alternately excites each input and output sensor, the receiver connected to the first switching device, the first e switching device installed with the possibility of connecting each sensor to the receiver, and a second switching device connected to the pathogen and the receiver, switching devices are made in the form of keys of a L-shaped structure, a matching resistance (Z1) is connected directly to the output of the pathogen, directly to the input of the receiver connected matching resistance (Z2), approximately equal to (Z1), the resistance of any key (Rcl) is much less than matching resistance (Z1, Z2), and matching resistance the value does not exceed triple the resistance of the sensors according to the ratio Rcl << Z1≈Z2 <3 | Z of the sensor |, the first switching device is made in the form of 2N keys, the number of which is equal to the number of sensors and each key is connected in series with one sensor, all keys are connected in series with the sensors are connected (connected) to one point, which is the connection point of two more keys of the second switching device, the first of which is connected to the exciter output with matching resistance (Z1), and the second to the receiver input and a terminating impedance (Z2).

The terminating resistance (Z1) can be connected in series with the output of the exciter and the first key of the second switching device.

The terminating resistance (Z1) can be connected in parallel with the exciter output, which is connected to the first key of the second switching device.

The terminating resistance (Z2) can be connected in series with the input of the receiver and the second key of the second switching device.

The terminating resistance (Z2) can be connected in parallel with the input of the receiver, which is connected to the second key of the second switching device.

The implementation of the switching devices in the form of keys of a L-shaped structure increases the degree of isolation of the open terminals of the key, which reduces the level of interference at the output of the open key. This, in turn, reduces the noise level at the output of the receiver. In addition, each of the sensors of the flowmeter is a volume resonator, that is, each of the sensors is capable of storing a significant amount of acoustic energy. As a result, after the completion of the probing signal, the sensor continues to generate a gradually damped spurious harmonic signal, the decay rate of which is determined by the value of the quality factor of the sensor. The specified spurious signal has a spectrum that practically coincides with the spectrum of the useful signal in the flowmeter path, that is, it is in the passband of the receiver filters, so its frequency selection is not possible. An increase in the signal attenuation in the open keys of the L-shaped structure reduces the level of the spurious signal penetrating through the open key, thereby reducing the level of interference from the spurious signal at the input of the receiver, therefore, the signal-to-noise ratio at the output of the receiver improves. The presence of a second switching device, made in the form of keys connected in series with the output of the pathogen and with the input of the receiver, protects the receiver from the effects of the probe signal of large amplitude, that is, increases the linearity of the receiver and helps to achieve an identical GWZ signals received on and against the flow of the controlled medium. Thus, the contribution of the receiver to the zero offset of the flowmeter will be minimal even when receiving signals with a small delay time relative to the probing signal.

The terminating resistance (Z1) is connected in series directly with the output of the pathogen if (Z1) is connected to the pathogen that contains a low voltage output voltage amplifier, and the terminating resistance (Z1) is connected in parallel directly to the output of the pathogen if the pathogen contains an amplifier with high output resistance . The terminating resistance (Z2) is connected parallel to the input of the receiver, if the receiver has a large input resistance of its own, the terminating resistance (Z2) is connected in series with the input of the receiver if the receiver has a low input resistance. The magnitude of the output resistance of the pathogen and the input resistance of the receiver should be compared with the value of the resistance of the sensor during evaluation.

Serial or parallel connection of matching resistances (Z1, Z2) depends respectively on the intrinsic resistance at the output of the exciter and at the input of the receiver, as was proved above. Adding matching resistances Z1 and Z2 ensures alignment of the output resistance of the exciter and the input resistance of the receiver. The equality of the indicated resistances is a necessary condition for ensuring the equality of the GVZ of the signals directed along and against the fluid flow in the measuring chamber, that is, it minimizes the measurement error due to the zero offset of the flow meter. In addition, terminating resistances (Z1, Z2) turn out to be common for signals directed along and against the flow of a controlled medium. Thus, the inevitably existing difference (Z1) from (Z2) has a minimal effect on the difference in the GWZ of the signals directed along and against the fluid flow. The resistance of any key (Rcl), which for the keys made on transistors, is essentially non-linear, should be much less than the matching resistances (Z1, Z2) so that its nonlinearity does not affect the zero offset of the flowmeter.

An increase in matching resistance Z1 << Z2 <3 | Z of the sensor | leads to an improvement in the ratio of matching linear resistance to spurious and non-linear resistance of the closed key. On the other hand, the attenuation coefficient of the signal in the open key is inversely proportional to the value of the matching resistance, which, from the point of view of the coefficient of transmission of interference to the input of the receiver, acts as a load for the key. In addition, an increase in matching resistance in the range above the resistance of the sensors leads to a decrease in the transmission coefficient of the signal from the output of the pathogen to the input of the receiver. Thus, an increase in matching resistance (in excess of the resistance value of the sensors) leads to a decrease in the zero offset of the flowmeter due to an increase in the linearity of the system and, on the other hand, increases the noise level at the output of the receiver. That is, it reduces the systematic error of the flow measurement by increasing the random measurement error. In this case, for the value of the matching resistance, there is an optimum, limited from below by a value of several key resistances, and from above - by a value of several sensor resistances. Within the specified optimum, a signal transmission coefficient acceptable for the flowmeter operation from the pathogen output to the receiver input is retained, and, therefore, an acceptable signal-to-noise ratio, while ensuring a sufficient degree of linearity of the sum of the resistance of the closed key and matching resistance.

The structure of the flowmeter switching device is made in such a way that all the keys in each channel of the signal from the exciter output to the input of the receiver are connected in series: one key in series with each input and output sensor plus a common key in series with the exciter output plus a common key at the receiver input. When measuring the delay time with respect to and against the flow, it turns out that the signal passes through four series-connected keys common to each sounding channel. Thus, when the signal is directed along and against the flow, the same “set” of keys is used, only the order in which the signal passes the keys connected in series with the sensors changes. As a result, the existing difference in the key resistances inevitably has a minimal effect on the difference in the GVZ of the signals directed along and against the fluid flow, i.e., on the zero offset of the flow meter.

Patent studies have shown that the proposed technical solution is new. Tests of the prototype showed that this technical solution is industrially applicable.

In fig. 1 is a functional diagram of an ultrasonic flowmeter with one acoustic channel, in which the matching resistance Z1 is connected in series with the exciter output, and the matching resistance Z2 is connected in parallel with the receiver input;

- in fig. 2 is a functional diagram of an ultrasonic flowmeter with one acoustic channel, in which the matching resistance Z1 is connected in parallel with the exciter output, and the matching resistance Z2 is connected in series with the receiver input;

- in fig. 3 is a functional diagram of an ultrasonic flowmeter with one acoustic channel in which the matching resistance Z1 is connected in series with the exciter output and the matching resistance Z2 is connected in series with the receiver input;

- in fig. 4 is a functional diagram of an ultrasonic flowmeter with one acoustic channel, in which the matching resistance Z1 is connected in parallel with the exciter output and the matching resistance Z2 is connected in parallel to the receiver input;

- in fig. 5 shows, by way of example, a functional diagram of an ultrasonic flow meter with three acoustic channels;

- in fig. 6 as an example, a key with an L-shaped structure.

The ultrasonic flow meter (Fig. 1) contains a measuring chamber 1 installed in the fluid flow 2, pathogen 3, receiver 4, the first matching resistance 5 (Z1), the second matching resistance 6 (Z2), the second switching device, consisting of two keys 7 and 8, the first switching device, consisting of N key pairs 9 and 10, input sensors 11 and output sensors 12, processor 13. The matching resistance 5 (Z1) can be connected in series with the output of the exciter 3 and the first key 7 of the second switching device (Fig. . 13). Matching resistance 5 (Z1) can be connected in parallel with the output of the pathogen 3, which is connected to the first key 7 of the second switching device (Fig. 2, 4). The terminating resistance 6 (Z2) can be connected in series with the input of the receiver 4 and the second key 8 of the second switching device (Fig. 2, 3). The terminating resistance (Z2) can be connected in parallel with the input of the receiver 4, which is connected to the second key 8 of the second switching device (Fig. 1, 4).

Each pair, consisting of an input and an output sensor, forms one acoustic channel. The causative agent 3 can be made in the form of a signal synthesizer, controlled by the commands of the processor 13, with the possibility of filtering and amplification of the generated signal. The causative agent 3 can be implemented in the form of a device that provides filtering and amplification of signals in analog form generated by the processor 13. The receiver 4 can be made in the form of a voltage amplifier with a low level of intrinsic noise, equipped with filtering (for example, band-pass) of the received signal. The receiver 4 can be equipped with gain control means under the control of the processor 13. The measuring chamber 1 can be made in any way, for example, in the form of a straight cylinder on which sensors 11 and 12 are mounted at an angle to the axis of the cylinder. Moreover, in each acoustic channel of the steam flow meter sensors 11 and 12 can be located both opposite to each other, providing transceiver of the acoustic signal of direct passage, and with the possibility of transceiving the reflected, including repeatedly, acoustic signal. The acoustic channels of a multichannel flowmeter (i.e., a flowmeter containing more than one pair of sensors, N> 1) can be located both in one plane (section of the measuring chamber), and in several, including intersecting planes (sections). The processor 13 can be made in the form of a standalone processor with the necessary peripheral equipment, a microprocessor, a microcontroller, a digital signal processor, programmable logic chip (FPGA), a specialized integrated circuit or any other similar device.

In fig. 1, 2, 3, and 4, flowmeters are shown with one acoustic channel containing one input sensor 11 and one output sensor 12. In Fig. Figure 5 shows a flowmeter with three acoustic channels, the first acoustic channel is formed by an input sensor 11.1 and an output sensor 12.1, the second by sensors 11.2 and 12.2, the third by sensors 11.3 and 12.3, respectively. Moreover, the first switching device 9 and 10 consists of three key pairs 9.1, 9.2, 9.3 and 10.1, 10.2, 10.3, respectively. In fig. Figure 6 shows an example of an L-shaped key.

Ultrasonic flowmeter operates as follows. In each acoustic channel, the flowmeter alternately measures the delay time of the signal in the direction of the fluid flow (T1), then against the fluid flow (T2). In addition, the flow meter calculates or measures the difference in the delay time of the acoustic signal (ΔT) using the processor 13. The measurement procedure {T1, T2, ΔT} is repeated at the highest possible rate, for example, tens of times per second. The obtained measurement results are subjected in the processor 13 post-processing, including filtering. From the obtained filtered values {T1, T2, ΔT} for each acoustic channel and the known geometric dimensions of the measuring chamber, the flowmeter calculates the volumetric flow rate of the fluid.

Consider the procedure for measuring the delay time of a signal by flow (T1) in the first acoustic channel formed by the first input 11 and output 12 sensors of the first acoustic channel. The processor 13 generates a sounding signal. In this case, the key control signals are generated by the processor 13 in such a way that the keys 7 and 9 are closed, the remaining keys are open. The probe signal generated by the pathogen 3 through closed keys is fed to the input sensor 11. The input sensor 11 converts the electrical signal into an acoustic signal and directs the acoustic signal in the first acoustic channel through the fluid to the side of the output sensor 12. At the end of the formation of the probe signal, the processor 13 generates key control signals so that the keys 7 and 9 open, and the keys 8 and 10 are closed. Due to the fact that the key 8 during the formation of the probe signal was open, the receiver 4 is not subjected to overload.

The phenomenon of drag of acoustic vibrations by the flow of the medium leads to the fact that the speed of movement of the acoustic signal is equal to the sum of the speed of sound in the medium and the projection of the flow velocity on the axis of the first acoustic channel.

Having reached the output sensor 12, the acoustic signal is converted into electrical form. Through the closed keys 10, 8, the received electrical signal is fed to the input of the receiver 4. Passing the receiver 4, the amplified and filtered received signal is fed to the input of the processor 13, which performs the necessary signal processing and provides measurement of the signal delay time by the fluid flow (T1). Then, the processor 13 generates key control signals so that the key 8 opens, the key 7 closes, the key 10 remains closed. The remaining keys are open. The procedure for measuring the delay time is repeated with the difference that the electrical signal is converted into an acoustic signal and sent to the first acoustic channel by the output sensor 12, in the opposite direction to the flow. The acoustic signal received by the input sensor 11 is converted into an electric signal and transmitted through the keys 9, 8 and the receiver 4 to the input of the processor 13. As a result of the processing of the received signal by the processor 13, the signal delay time against the fluid flow (T2) will be obtained, and the combined processing and against the flow of signals will allow you to get ΔΤ. The resulting set of instantaneous measurement results {T1, T2, ΔΤ} of the first acoustic channel is processed in the processor 13, which calculates the flow rate of the fluid.

For flowmeters with more than one acoustic channel, for example, three acoustic channels and N = 3 (Fig. 5), the measurement takes place in each acoustic channel in turn. After completion of the measurement in the last acoustic channel, the measurement process is repeated cyclically, starting from the first channel. As a result, an array can be obtained, for example, from three instantaneous measurement results {T1, T2, ΔΤ} ₁ , {T1, T2, ΔΤ} ₂ , {T1, T2, ΔΤ} ₃ . All these measurement results are used simultaneously when calculating the volumetric flow rate by the processor 13. When calculating the volumetric flow rate, the processor 13 uses, along with the arrays obtained, information on the geometric dimensions of both the measuring chamber 1 as a whole and each acoustic channel in particular. After completing a single measurement in the first acoustic channel, the processor 13 cyclically repeats the measurement procedure {T1, T2, ΔΤ} _i for the remaining acoustic channels. The difference between the measurement process and the described one lies only in the fact that during sensing and reception, the processor generates key control signals 9.2 ÷ 10.N in such a way that the keys connected to the sensors of the currently operating acoustic channel of the flowmeter are short-circuited. At the same time, during the measurement of T1 in each acoustic channel, the input sensor of the corresponding acoustic channel is connected to the pathogen 3 during the formation of the probing signal, and reception is carried out from the output sensor of the same acoustic channel. During T2 measurement, the output sensor of the corresponding acoustic channel is connected to the exciter 3, and the input sensor of the same channel is connected to the receiver 4.

The problem of reducing the measurement error of the flow rate is solved due to the fact that the values of the matching resistances (Z1) and (Z2) are selected so that the output resistance of the exciter taking into account the matching resistance (Z1) connected to its output - (for example, Rв + Z1) It turned out to be as close as possible to the input impedance of the receiver (for example, Rpr || Z2) taking into account the matching resistance connected to the input of the receiver (Z2). In particular, if an exciter with a low intrinsic output impedance is used, and an amplifier with a high output impedance is used as a receiver, Z1 = Z2 will be optimal. An analysis of the signal transmission from the pathogen to the receiver, provided the medium is stationary in the measuring chamber of the flowmeter, that is, on the assumption of an equivalent electrical circuit in which a delay line with a delay T1 = T2 = T is connected between the sensors, shows the following. The minimum delay time difference (T1-T2) will be achieved if the output resistance of the exciter is equal, taking into account the connected (Z1) input resistance of the receiver, taking into account the connected (Z2). For example, (Rb + Z1) = (Rpr || Z2). That is, the zero offset of the flow meter in this case will be minimal. In addition, if you select [(Rв + Z1) = (Rпр || Z2)] ≈Z sensors, the transmission coefficient of the signal from the pathogen to the receiver, in the channel formed from the pathogen, keys, sensors, the medium in the measuring chamber and the receiver will be maximum at subject to the inequality Rcl << R sensor.

The implementation of complex matching resistances Z1 and Z2 containing reactances that compensate for the reactive component of the resistance of the sensors allows minimizing the voltage drop on the reactivity of the sensors, which is useless for transmitting power, and therefore, increasing the power transmitted from the output of the exciter to the input of the signal receiver.

Thus, a noticeable improvement in signal to noise ratio can be achieved. The use of complex keys with an L-shaped structure increases the attenuation of the signal in an open key, and, therefore, minimizes the contribution of the exciter noise and interference arising from the accumulation of energy in the sensors (which are volume resonators) to the noise level at the output of the receiver. That is, the complication of the structure of the keys in the flowmeter leads to a decrease in both the random component of the measurement error due to noise and the systematic error in the measurement of flow due to spurious acoustic signals, which are generated due to the energy reserve in the sensor that formed the probe signal. The choice of the value of the matching resistance in the specified dynamic range between the resistance of the key and several resistance of the sensor allows you to optimize the linearity of the path, consisting of a pathogen, keys, matching resistances, sensors and receiver, while maintaining an acceptable coefficient of signal transmission from the pathogen to the receiver, that is, a good ratio signal to noise output of the receiver. The linearity of the path provides the identity of the GWZ of the signals directed to and against the fluid flow, which is necessary to minimize the zero offset of the flow meter, and a good signal-to-noise ratio minimizes the random component of the error in the flow measurement.

Claims (5)

1. An ultrasonic flow meter containing a measuring chamber mounted in a fluid stream, N — pairs of input and output sensors mounted on the measuring chamber, an exciter, a first switching device connected to the sensors and the exciter and installed between the sensors and the exciter with the possibility of selective connection of the sensors with the pathogen, and the pathogen alternately excites each input and output sensor, a receiver connected to the first switching device, the first switching device, installed with the possibility of connecting each sensor to the receiver, and a second switching device connected to the exciter and the receiver, characterized in that the switching devices are made in the form of keys of a L-shaped structure, a matching resistance (Z1) is connected directly to the output of the exciter, directly to the input of the receiver included matching resistance (Z2), approximately equal to (Z1), the resistance of any key (Rcl) is much less than matching resistance (Z1, Z2), and matching resistance values do not exceed triple the resistance of the sensors according to the ratio Rcl << Z1≈Z2 <3 | Z of the sensor |, the first switching device is made in the form of 2N keys, the number of which is equal to the number of sensors and each key is connected in series with one sensor, all keys connected in series with the sensors ( connected) to one point, which is the connection point for two more keys of the second switching device, the first of which is connected to the output of the exciter with matching resistance (Z1), and the second to the input of the receiver with consent resisting resistance (Z2). 2. The ultrasonic flow meter according to claim 1, characterized in that the matching resistance (Z1) is connected in series with the output of the pathogen and the first key of the second switching device. 3. The ultrasonic flow meter according to claim 1, characterized in that the matching resistance (Z1) is connected in parallel with the exciter output, which is connected to the first key of the second switching device. 4. The ultrasonic flow meter according to claim 1, characterized in that the matching resistance (Z2) is connected in series with the input of the receiver and the second key of the second switching device. 5. The ultrasonic flow meter according to claim 1, characterized in that the matching resistance (Z2) is connected in parallel with the input of the receiver, which is connected to the second key of the second switching device.

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