UA40788C2 - Device for calibrating water flow rate meters - Google Patents

Abstract

The proposed device for calibrating water flow rate meters contains an accumulating reservoir, at least two measuring vessels with water-gauge tubes, a unit for creating laminar water flow, a unit for controlling water flow rate, water flow rate transducers, an optoelectronic unit for reading output data of the water flow rate transducers, level transducers, and water physical parameter transducers installed in the accumulating reservoir, measuring vessels, and water-gauge tubes, inlet and outlet electromagnetic valves, a measurement data input unit, a control and computing unit, and a data output unit. The control and computing unit provides statistical processing of the measurement data. The proposed device contains the cylindrical measuring vessels made of stainless steel. The proposed device provides for increasing the measurement accuracy at low water flow rates and is characterized by improved speed of response.

Description

Description of the invention

The invention relates to the field of instrumentation, namely: the production and application of devices for 2 metrological certification, verification, calibration, research and testing of liquid quantity meters of various designs and operating principles.

A well-known automated test system for determining the relative error of cold water meters, containing a device for refueling and storing water, a tank, a pump unit and devices for regulating and stabilizing the flow, which ensure smooth regulation of the flow, and means for measuring the flow in the entire 70 range of test flows, shut-off devices with a manual, pneumatic or electric drive, a test station intended for connecting meters to the line of the verification system, an exemplary device for measuring the volume of water, an optoelectronic node for capturing signals that produces pulses that correspond to the indicators of the rotation of the meters, a device for normalizing measurement information that synchronizes the start of the countdown signals of measurement information with the start of measurement of the exemplary measure of the liquid that passed through the meters being checked 72 and the termination of the count at the end of the measurement, the control unit designed to ensure the necessary sequence of operations and the form recording of measurement information signals in a form convenient for reading the readings and comparing them with the readings of standard meters and reference meters

The principle of operation of the device is to measure the amount of water passing through the meter in a given time interval, while the amount of water is automatically read from the signal stars of the meters by an optoelectronic counter and pulse counters, for example. BSY-10 (See STATE STANDARD 8. 156 - 83, p. 23).

The disadvantage of the known device is its low accuracy, which limits the possibilities of use as a sample tool, as well as the measurement error arising from the failure to take into account the physical parameters of the liquid to be measured, environmental parameters that affect accuracy, etc., and also due to the not completely eliminated methodical measurement error associated with a change in the speed of the liquid flow passing by the wings of the counter stars, especially with small amounts of liquid passing through the system, with a change in the height of the liquid column and the impossibility of organizing the measurement process under the time of passage through the system of parts of a sample volume of liquid or multiple passage of the same or different volumes of liquid along a closed circuit of the measuring path of the installation. co

The closest in technical terms is a device for checking liquid quantity meters, containing a tank, measuring containers with water measuring tubes, a pump unit, a laminar flow forming unit, a flow control unit, a unit of water meters to be checked, an optoelectronic information reading unit, and sensors liquid level sensors placed on the water measuring tubes of all measuring containers, and sensors of physical parameters, Ha") placed in the tank and all measuring containers, inlet and outlet electric valves, a controller for inputting 3o measuring information, a control computing device and an information output device, in which the output C of the tank is connected to the pump block, the laminar flow formation block, the flow regulation block and the block of water meters that are being checked, the output of the block of water meters that is being checked is connected through the inlet electrovalves to the inputs of all measuring containers, the outputs of which are through " outlet solenoid valves are connected to the tank inlet a, the control inputs of the electric valves are connected to the first and second outputs of the input controller of measuring information: the first group of inputs of which is connected to the outputs of physical parameter sensors and to the outputs of liquid level sensors, the second group of inputs of the input controller

From" measuring information is connected to the outputs of the measuring information reading unit, the inputs of which are connected to the information outputs of the water meter unit being tested, the second group of outputs of the controller of the measuring information input is connected to the inputs of the control computing device, the output of which is connected to the input information output device. (See Patent of Ukraine No. 23801 A dated 16.06.98) Shk The disadvantages of this device are its insufficiently high accuracy and stability, which limits the possibilities of av! its use as a sample tool when measuring relatively small amounts of liquid, as well as the methodological error of measurements is not completely eliminated, associated with a change in the speed of the flow of liquid passing by the wings of the counter sprockets, when the volume of liquid passing through the system changes you height of the liquid column by 20 | due to non-target laminar properties of the formed flow, as well as not high speed, which is explained by the impossibility of carrying out measurements and obtaining intermediate results during the flow of parts of the volume being measured. i.e. "on the move". In addition, the device cannot be used when checking meters that are not equipped with signal sprockets with mirror wings, but only with generators of electric pulses that occur when the wings of the meter sprockets rotate when the liquid flow being measured passes by them. 29 The invention is based on the task of improving the device for checking liquid quantity meters, y

HF) in which increasing the accuracy of measuring relatively small amounts of liquid and increasing the overall speed of the device is achieved by reducing methodical measurement errors due to the use of several measuring containers of a special shape, taking into account a greater number of physical parameters of the liquid, the amount of which is measured, parameters of the formed liquid flow and the environment, as well as determining with the help of a 60 control computing device that automates the measurement process and processes its results, the instantaneous frequencies (or periods) of the rotation of the wings of the stars of the sample and recirculation counters of the amount of liquid, the comparison of the results obtained in different time intervals of the flow of the liquid being measured , and determining the statistical characteristics of the obtained realizations of the measured physical quantities, in order to take into account and correct their temporal non-stationarity. because the set task is achieved by the fact that the device, which contains the tank, has measuring points (at least two)

of a special form with water measuring tubes, a pump unit, a laminar flow formation unit, a flow control unit, a unit of tested water meters, an optoelectronic unit for reading information from signal lights equipped with mirror wings, liquid level sensors and sensors of physical parameters placed in the tank, each from measuring containers and water-measuring tubes, inlet and outlet electric valves, a controller for inputting measurement information, a control computing device and an information output device, in which the outlet of the tank is connected to the pump unit connected in series, the laminar flow forming unit, the flow control unit and the water meter unit , which are checked, the output of the block of water meters, which are checked, is connected through the inlet electrovalves to the inputs of all measuring containers, the outputs of which are through 7/0. group of outputs) ko the input controller of measurement information, the first group of inputs of which is connected to the outputs of physical parameter sensors and the outputs of liquid level sensors, the second group of inputs of the input controller of measurement information is connected to the outputs of the optoelectronic unit for reading measurement information from signal stars equipped with mirror wings, the inputs of which are connected to /5 by optical information outputs of the units of the water meters being tested, the second group of outputs of the controller of measurement information input is connected to the inputs of the control computing device, the output of which is connected to the input of the device of information output, in addition, the third group of inputs of the controller of input of measurement information is connected with the pulsed information outputs of the unit of water meters being tested, the third group of outputs of the controller of the input of measurement information is connected to the control inputs of the pump units, the flow control unit and the laminar flow generator, and the control computing device is equipped with by means of statistical signal processing.

The shape of the measuring containers plays an important role and largely determines the metrological parameters of the device, especially when running relatively small amounts of liquid through the system. In the proposed device, all measuring containers are given a cylindrical shape with conical upper and lower ends and thinning of the EXHAUST nozzles with adjustable diaphragms, and the ratio of the heights of the cylindrical and conical parts is chosen within 4 :(1 x 0.2): (1 - 0.2), the angle of inclination of the creative conical ends to the plane of the base - within i) limits of (45 mm - 10)", all measuring containers are conformal, that is, the ratio of all their sizes does not change when the absolute dimensions (volume) of the container for creation of various reference volumes of liquid, and all linear dimensions of measuring containers change in V times, where so z in (Mi)

Mita M" - volumes of various measuring containers (as a rule, 10...50 liters). co

At the same time, the containers are made of corrosion-resistant material, for example, stainless steel. This shape facilitates the complete outflow of liquid from the container (lower cone) and the complete removal of air from the container during filling (upper cone). at

Due to the introduction of new elements and relationships, it is possible to increase the metrological "Its characteristics of the system for checking liquid quantity meters and to significantly reduce the control volumes of liquid that are necessary for checking, which, in turn, reduces the dimensions and weight of the system, as well as reduces its energy consumption, increases the productivity and speed of the device and allows you to organize the process of measurements during the passage through the system of parts of a sample volume of liquid, or multiple passage of the same, 70 or different volumes of liquid along the closed circuit of the measuring path of the system. - c An example of the implementation of the proposed device can be an automated workplace (ARM) of a metrologist for checking liquid quantity meters on the basis of specialized or universal mini- or "» micro-computers, or universal personal IVM-compatible computers with built-in or specialized controllers connected to the computer by the circles of standard interfaces

Figure 1 shows the structural diagram of the proposed device, which shows! tank 1, measuring "g" containers (at least two) 2.1 with water measuring tubes 3.1 pump unit 4, laminar flow formation unit 5, flow control unit 6, water meter unit 7, optoelectronic information reading unit 8, inlets 9.1 o and outlets 9.2 electrovalves 9 (9.K.Y), level sensors 10 (10.1, 10.2,... 10th), sensors of physical parameters -I 11, measurement information input controller 12, control computing device 13 with statistical signal processing unit 14, the information output device 15, each measuring capacity 2, consists of a cylindrical nozzle 16 with an adjustable diaphragm, a cylindrical part 17, an upper 18 and a lower 19 conical ends.

Fig. 2 shows the structural diagram of the prototype, on which the blocks of the same name as the proposed device are marked with the same numbers-positions.

The device for checking the meters of the amount of liquid offered functions as follows.

From the reservoir 1, which is pre-filled with the liquid to be measured, by means of the corresponding on

Ф, according to pump block 4, through the covered electric valves 9.К.Й, the flow regulated by the liquid flow control block b occurs, which flows in a circle: tank 1 - pump block 4 - laminar flow formation block 5 - flow control block 6 - block of controlled water meters 7 - inlet valves 9.1.) - measuring containers 2.1 - outlet valves 9.2.) - tank 1. The flow path is selected by selecting | that is, by closing the corresponding valves 9.K.i. Information from sensors of physical parameters 1.1, optoelectronic unit 8 for reading information from controlled counters 7 and liquid level sensors 10 installed on water measuring tubes 3.|. measuring containers 2nd. through the corresponding inputs of the input controller, the measurement information 12 comes from its outputs to the inputs of the control computing device 13, which 65 automates the measurement process and processes its results, recording the results of measurements of physical parameters 11 and levels 10, comparing the results of measurements made by the reference and controlled counters 7, determining the measurement error of each of the counters 7 and inducing all the obtained results on the indicators of the information output device 15, in addition, the information from the pulse outputs of the controlled counters 7 is also sent to the third group of inputs of the controller of the input of measurement information 12 After the end of the verification process, the control computing device 13 turns off the pumps of the block pumps 4 and closes the inlet and outlet electric valves 9.K.). To expand the area of possible use of the device to such liquid meters that are being tested, the measuring sprockets of which are not equipped with mirror wings, the connection of the controller of the input of measurement information 12 with both (optoelectronic and pulse) groups of outputs of the water meter block 7 is provided.

Flow control units b and formation of laminar flow 5 provide the possibility of checking water meters 7 with various values of throughput with high accuracy in accordance with the requirements of STATE STANDARD 8.156-83 due to the elimination of flow pulsations arising due to the operation of pumps and other hydraulic devices. The presence of several (at least two) measuring containers 2.) of different capacity and a flow path switch, which is implemented on several electrovalves 9,K.| (K - inlet or outlet, | - the number of the measuring capacity and flow path), which are switched synchronously, is explained by the need to ensure the possibility of checking liquid quantity meters, which are designed for different maximum liquid flow rates.

At the same time, the application of the proposed device, due to the use of measuring containers of a special shape, taking into account parameters that were not taken into account before, as well as due to the use of a control computing device in its structure, which controls the technological process of measurements and processing 2o output signals of sensors, provides a significant increase accuracy of measurements and allows its use as an exemplary tool during metrological attestation operations and verification of liquid quantity meters. and also allows you to organize the process of measurements during the passage through the system of parts of a sample volume of liquid or multiple passage of the same or different volumes of liquid along the closed circuit of the measuring path of the system. with

In the device, which contains tank 1, measuring containers 2. (at least two) of a special form with water measuring tubes 3.), block of pumps 4, block 5 of formation of laminar flow, block b of flow control, block 7 i) counters of the amount of liquid that are checked, the optoelectronic unit 8 for reading information from the signal stars of the counters, which are equipped with mirror wings, sensors 10.i). liquid level and sensors of 11 physical parameters, placed in the tank and each of the 2nd measuring containers. and water measuring tubes 3.), inlet and outlet electrovalves 9.K.., controller 12 for the input of measurement information, control computing device 13 and device for outputting information 15, in which the output of the tank 1 is connected to the data connected in series with the block pumps 4, block 5 of laminar flow formation, flow control block 6 and block M 7 of the water meters being tested, the output of the block 7 of the water meters being tested is connected through the inlet electrovalves 9.1.). with the inputs of all measuring containers 2 |., the outputs of which are through the outlet electrovalves at 9.2.1. connected 5 by the input of the tank 1, the control inputs of the electric valves 9.K.Y are connected to the first and second "E outputs (the first group of outputs) of the controller 12 of the input of measurement information, the first group of inputs of which is connected to the outputs of the sensors of physical parameters 11 and to the outputs of the sensors 10 liquid level, the second group of inputs of the controller 12 for inputting measurement information is connected to the outputs of the optoelectronic unit 8 for reading measurement information from the signal stars of counters 7 equipped with mirror wings, "

INPUTS OF WHICH are connected to the optical information outputs of the block 7 of the water meters being tested, the second pl) s group of outputs of the controller 12 of the input of measurement information is connected to the inputs of the control computing device 13, the output of which is connected to the input of the information output device 15, in order increasing accuracy;" measurements with their accelerated/expanded scope of application and automation of the technological process additionally introduced a third group of inputs of the controller 12 for inputting measurement information, connected to the impulse information outputs of unit 7 of the water meters being tested, a third group of outputs of the controller 12 for inputting their measurement information, in It is connected to the control inputs of the pump unit 4, the flow control unit b and the laminar flow generator 5, and the control computing device 13 is equipped with a statistical signal processing unit 14. -I Some nodes of the system may be missing during the construction of its various configurations, which are determined by the specific types of counters 7 that are checked, their number and accuracy, and the frequency of checks that are required. c The device functions as follows: from the reservoir 1, which is previously filled with the liquid to be measured, with the help of the pump unit 4, which is turned on accordingly, through the electric valves 9, K, which are opened with the help of the control computing device 13 and the controller 12 for the input of measurement information.

There is a flow of fluid regulated by the fluid flow control unit 6, which flows around the tank 1 - pump unit 4 - laminar flow formation unit 5 - flow control unit 6 - unit

F) controlled water meters 7 - inlet valves 9.1 | - measuring containers 2| - exhaust valves 9.2.) - tank 1. Information from the sensor of physical parameters 11, installed in tank 1 and measuring containers 2. |. and the 10th liquid level sensor, installed on the water measuring tubes 3. of the measuring containers 2.І. from the outputs of the optoelectronic unit 8, reading information from the unit of controlled counters 7 and from the pulse information outputs of the unit of controlled meters 7 through the appropriate groups of inputs of the input controller 12 of the measurement information is received from one of its groups of outputs to the corresponding inputs of the control computing device 13, which automates the measurement process and processes its results, recording the measurements of sensors of physical parameters 11 and levels 10. comparing the results of measurements performed 6b5 by the reference and controlled counters 7, determining the measurement error of each of the counters 7 and inducing all the obtained results on the indicators of the information output device 15. In addition, information from pulse outputs of the counters 7 is also sent to the third group of inputs of the controller of the input of measurement information 12. After the verification process, the control computing device 13 turns off the pumps of the pump block 4 and closes the inlet and outlet electric valves 9.K.).

To expand the area of possible use of the device to such liquid meters that are being tested, the measuring sprockets of which are not equipped with mirror wings, the connection of the controller of the input of measurement information 12 with both (optoelectronic and pulse) groups of outputs of the water meter block 7 is provided.

The controller 12 of the input of measurement information converts the electrical analog signals coming from the outputs of the sensors 11 and 10.i, as well as from the outputs of the optoelectronic unit 8 of reading information from the information 7/o outputs of the unit 7 of the liquid quantity counters being tested, into codes suitable for their reception by the control computing device 13, at the same time, are installed on the measurement information input controller 12 or implemented software in the environment of the control computing device 13. The counters count the pulses coming from the pulse information outputs of the block 7 of the counters of the amount of liquid being tested, the frequency of which proportional to the fluid flow rate, and their number is proportional to its volume. Placed on water measuring tubes 3.| of all measuring containers 2.) at a given height, one above the other, the 10th (for example, optoelectronic) level sensors of the liquid to be measured provide a sequence of electrical fluctuations that occur when the light flux of the next optoelectronic sensor 10 crosses the upper section of the falling liquid column i.e., the controller 12 transforms the time intervals between the fronts of the electrical surges into the corresponding digital values, which are then processed by the controlling computing device 13. Given the known total area 5. M; between the upper section of the water measuring tube and the location of the sensor 10. it is easy to determine the amount of M; of the liquid that passed between the upper section of the water measuring tube 3.| of the selected measuring capacity 2 | and the first sensor of level 10.1 or between sensors 10.i and 10i-1), according to the formulas:

Mrzhihi|x(I)- pi) or p

Min Eh v.) x(p;- pin), where

I.) - the height of the upper section of the water measuring tube 3.) of the corresponding measuring container 2.). and)

Corresponding maximum, minimum and average values are also determined. | errors of their measurement at different flow rates of liquids being measured.

Determined by counting the number of pulses from the information outputs of the counter block 7, which are checked, the value of M ;); for a given segment and passage of a measuring container 2.) or a water measuring tube 3.Y by liquid, at the given moment of time it is proportional to M, and (with known parameters of the containers, tubes and physical parameters of the liquid) and is equal to M; with a given degree of accuracy. In the absence of optoelectronic outputs with the results of measurements of M in the block of meters 7, which M are checked; only the calculated number of pulses coming from the pulse information outputs of block 7 are compared, and in the absence of sensors 10 in the block system - these results are compared between the reference counter of block 7 and the counters that are checked. At the same time, the instantaneous frequency of the appearance of these pulses i ;;);, both for the pulses coming from the outputs of the optoelectronic unit 8 and for the pulses coming from the pulse information outputs of the counters 7 being checked, because it is clearly related to the flow rate,

Connected, in turn, with the measured parameter by known obvious relationships, while "

The measurement of this frequency requires much less time than the measurement of full or even partial H;;); can /- s be carried out repeatedly in the process of running the same amount of liquid and even makes it possible to carry out

And the adjustment of individual counters of block 7, which do not fit within the given error, right in the course of flow and? another portion of liquid. The frequencies to be measured are of the order of Hz units and can be measured by any of the known means of measuring the frequency of low-frequency oscillations, including the vernier method, the method

Measurement of instantaneous periods converted to frequency, application of statistical averaging, selection of amplitude and frequency envelopes of a modulated signal, calculation of spectral density and power in this frequency range, etc. d., etc. o Correction and clarification of the obtained results is carried out using the same control computer-I device 13 with a block 14 of statistical processing of signals, taking into account the measured and digitized by the controller 5or 12 input measurement information of the signals of sensors 11 of physical parameters. All these calculations are performed by the same controlling computing device 13 in real time, which, if we take into account the very low frequency range of signals, does not require significant computing costs and significant processing time of the controlling computing device. The use of spectral processing methods also allows taking into account the non-absolute laminarity of the formed liquid flow, which is caused by the residual pulsation of the liquid under the action of the 5B unit of pumps 4 together with the resonant properties of the overall system, while the parameters corresponding to the constant component frequency of the frequency envelope of the disassembled signal can be determined separately and separate

F) harmonics of its variable components, with a possible correction of laminarity or consideration of uneliminated laminarity in the measurement results of the reference and controlled counters 7, for this purpose the connection of the third group of outputs of the controller 12 of the measurement information input with the control inputs of the pump unit 5, the flow control unit is provided 5 and block 6 of laminar flow formation. The obtained results are compared with the results of the measurement of the amount of liquid by the meters 7 being checked, which are sent to the control computing device 13 from the information outputs of the meters 7 through the optoelectronic unit for reading the measurement information 8 and the controller 12, which counts the "packs" of electric pulses and converts their number to the Dream, proportional to the amount of liquid flowing through each counter 7, into a digital code, and/or 65 determines the instantaneous period (the time interval between two adjacent or distant from each other by a specified number) pulses, and then converts it into an instantaneous frequency, or simply determines the desired frequency of Her.

The relative errors of measuring the amount of liquid by each of the counters 7 are determined and a conclusion is made about the compliance or non-compliance of each of the counters with its accuracy class by comparison with the maximum relative error of the measurements, while the results of the measurements are induced by the information output device 15 both during the measurements and after their completion . It is also possible to create an automated inspection protocol with all the necessary parameters, tables and conclusions, which only needs to be output to a standard documentation device. signature of the commission or system operator and reproduction.

The shape of the measuring containers plays an important role and largely determines the metrological parameters of the device, especially when running relatively small amounts of liquid through the system. In the proposed device, all 7/0 Measuring containers are given a cylindrical shape with conical upper and lower ends and thinning of outlet nozzles with adjustable diaphragms, and the ratio of the heights of the cylindrical and conical parts is selected within 40: (1 x 0.2): (1 x - 0.2), the angle of inclination of the creative conical ends to the plane of the base - within (45 x 10)", all ratios of the dimensions of the measuring containers do not change when changing the absolute dimensions of the container for creating various reference volumes of liquid, accepting all linear dimensions of the measuring containers / 5 Change in B times, where in (MiM2) i,

Mi and M" - volumes of various measuring containers (as a rule, 10...50 liters).

At the same time, the containers are made of corrosion-resistant material, for example, stainless steel. This shape facilitates the complete outflow of liquid from the container (lower cone) and the complete removal of air from the container during filling (upper cone).

Due to the introduction of new elements and relationships, there is an opportunity to increase the metrological characteristics of the system for checking liquid quantity meters and to significantly reduce the control volumes of liquid that are necessary for checking, which, in turn, reduces the dimensions and weight of the system, as well as reduces its energy consumption. increases the productivity and speed of the device and allows you to organize the process of measurements under Ga during passage through the system of parts of a sample volume of liquid, or multiple passage of the same or different volumes of liquid along the closed circuit of the measuring path of the system. i9)

On the basis of the same system, the meters of the amount of hot water and thermal energy can be checked.

An example of the implementation of the proposed device can be an automated workplace of a metrologist for checking liquid quantity meters based on specialized mini-or. micro-ECOM or universal so personal IVM-compatible computers. At the same time, the measuring information input controller 12 can be a node of a specially designed control computer device, built on the basis of one of the so sets of microprocessor sections, connected to the control computer 13 by lines of standard RF interfaces, or a plug-in board that is installed directly on the platform universal personal computer. Built into the control computer 13, the block 14 of statistical processing of signals can be implemented hardware-based on the basis of a signal processor, co-processor or software, and combined options are possible.

Claims (2)

The formula of the invention "- c 1. A device for checking water quantity meters, which contains a tank, measuring containers, not less . two, with water measuring tubes, a pump unit, a laminar flow formation unit, a flow control unit, and a unit of water meters that are checked, an optoelectronic unit for reading information from signal stars equipped with mirror wings, liquid level sensors and sensors of physical parameters located in the tank, in all measuring containers and water-measuring tubes, inlet and outlet electrovalves, a controller for inputting measurement information, a control computing device and an information output device, in which the outlet of the tank is connected to the pump unit connected in series, the laminar flow forming unit, and the flow control unit and by the block of water meters that are being checked, the outputs of the block of water meters that are being checked are connected through the inlet electrovalves to the inputs of all measuring containers, the outputs of which are through 5r The outlet electrovalves are connected to the tank inlet, the control inputs of the electrovalves are connected to the first group outputs of the input controller of measurement of information, the first group of inputs of which is connected to the outputs of physical parameter sensors and to the outputs of liquid level sensors, the second group of inputs of the controller of the input of measurement information is connected to the outputs of the optoelectronic unit for reading measurement information from the signal stars of meters equipped with mirror wings, the inputs of which are connected with optical two information outputs of the unit of water meters being tested, the second group of outputs of the controller of the input of measurement information is connected to the inputs of the control computing device, the output of which is connected to (F, the input of the information output device, which differs in that the third group of inputs controller of the input of measurement information is connected to the pulse information outputs of the block of water meters being checked, the third group of outputs of the controller of the input of measurement information is connected to the control inputs of the pump unit, the laminar flow formation unit and the flow control unit, and the control computer The device is equipped with a statistical signal processing unit. 2. The device according to claim 1, which differs in that the measuring containers are given a cylindrical shape with conical ends and a cylindrical filling nozzle, the diameter of which is selected depending on the required accuracy of volume measurement, the ratio of the heights of the cylindrical part to the conical part - depending on the required for 65 volume measurement, the angles of inclination of the conical ends to the base plane are 45:10 7, and the measuring containers are made of stainless steel. C. The device according to claim 1, which is characterized by the fact that the control computing device uses the results of information processing by the statistical signal processing unit, comparing the processing results with norms and with each other, including the results of measuring the instantaneous rotation frequencies of the signal sprockets of the Water meters being tested , and/or reference water meter. c schi 6) (ee) (ee) che «c) « - with . and? d" ("c) -I (ee) IR e) ime) 60 b5