RU2367819C1 - Method of proportioning reagents and device to this end - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: invention relates to water preparation and can be used in heat engineering and chemical industry. Proposed method comprises measuring fluid flow rate, generating a train of electric pulses corresponding to measured amount of fluid, sending aforesaid train of pulses to the input of 1^st pulse counter, generating a train of electric pulses corresponding to metering pump strokes and sending aforesaid train to the input of 2^nd pulse counter, simultaneously with counting the pulses corresponding to measured amount of fluid. Output circuits of 1^st switching device are consecutively switched, one of them being connected to metering pump drive motor. Output circuits of 2^nd switching device are consecutively switched, one of them being preliminary connected to 1^st pulse counter reset circuit. 1^st pulse counter being reset, 2^nd pulse counter reset circuit is closed to be reset. Proposed device comprises flow rate metre and two pulse counters connected with two switching devices.

EFFECT: simplified and reliable method and device.

10 cl, 2 dwg, 1 tbl

Description

Technical field

The invention relates to chemical technology, and more specifically to methods of water treatment by dosed introduction of chemical reagents, and to devices for dosed introduction of liquid reagents into a pressure pipe, and can find application, for example, in heat engineering, as well as in the chemical and petrochemical industries.

State of the art

A known method of volumetric dosing of liquids [1], in which the fluid flow is controlled by pulses, and the pulses are removed by a proximity sensor from a rotating gear located on the pump shaft.

The disadvantage of this method is the limited ability to control the proportion of dosing, which is determined by the number of pulses taken per revolution of the pump, and the difficulty of its regulation, due to the need to replace the gears.

Known metering pump with an electric motor [2], with a converter of rotational motion of the rotor into reciprocating motion, with a pump driven by this reciprocating motion, with electronic control, including a motor depending on an external pulse generator, in which each pulse corresponds to a certain amount of medium. The control device turns on the engine, which performed a certain part of the pump operation cycle, only when the number of pulses received from the external generator corresponds to the amount of medium equal to or greater than the dose that the pump delivers during the operation cycle. The control device determines the required dose of reagent according to the number of pulses received, subtracting from this amount the amount of supplied reagent to determine the required dose of reagent, and turns on the metering pump motor.

The disadvantages of the described construction include the complexity of the control device and its operation algorithm, including the implementation of mathematical operations to calculate the required dose of the reagent by subtracting the supplied amount of the reagent from the number of pulses received. The implementation of such an algorithm requires a complex logical structure of the control device and entails low reliability and noise immunity of this device.

The closest in essence and the technical result achieved to the claimed invention are a method of controlling a metering pump with an electric motor, as well as a metering pump with an electric motor [3]. A method for controlling a metering pump with an electric motor and electronic control for it includes measuring the liquid flow rate with an external pulse sensor, each pulse of which corresponds to a certain liquid flow rate, the required flow of the dosing agent being achieved through a series of external pulses and controlling the pump injection volume by controlling the electric motor. The sequence of external pulses is fed to the input of the first pulse counter. The dosing pump during operation generates a sequence of pulses that are fed to the input of the second pulse counter. The signals from the output of the first and second counters are fed to the inputs of the comparison device, and the pump is turned on in accordance with the output signal of the comparison device.

A metering pump with an electric motor includes a pump driven in a reciprocating motion by an electric motor and an electronic motor control device. The electronic control device contains a comparison unit for comparing the pulse sequence of the external pulse sensor with the sequence of pulses generated by the metering device during operation and return of the pump.

The disadvantage of the described method is its complexity, caused by the need to perform mathematical and logical operations to control the electric motor and regulate the amount of pump injection. The disadvantages of the device include the technical complexity of the control device, which includes a comparison unit. To implement the described device requires complex and scarce electronic elements, and the device itself is difficult to manufacture, commission and operate.

Disclosure of invention

The aim of the invention is to simplify, reduce the cost and increase the reliability of the method of dispensing a reagent and device for its implementation. The technical result, which is achieved by the claimed invention, is to simplify the method of dispensing the reagent, increase reliability, reduce the complexity and ease of use of the device for dispensing reagents, as well as the possibility of manufacturing the specified device on a simple and affordable element base.

The technical result is achieved in that a method of dispensing a reagent using a metering pump driven by a reciprocating motion of an electric drive includes measuring a liquid flow rate, generating a sequence of electrical pulses corresponding to a measured amount of liquid, supplying a sequence of pulses corresponding to a measured amount of liquid to an input of the first pulse counter, generating a sequence of electrical pulses corresponding to the doses its pump flow pulse sequence corresponding to strokes of the metering pump, to the input of the second pulse counter. In this case, simultaneously with the counting of the pulses corresponding to the measured amount of liquid, the output circuits of the first switching device are sequentially switched, one of which is pre-connected to the metering pump electric drive, and the output circuits of the second switching device are sequentially counted with the pulses corresponding to the metering pump moves, one of which is pre-connected to the reset circuit of the first pulse counter in the initial state yanie, and when the first pulse counter is reset to the initial state of the second short pulse counter reset circuit in its initial state.

Compared with the prototype, the fact that simultaneously with the counting of the pulses corresponding to the measured amount of liquid, the output circuits of the first switching device are sequentially switched, one of which is pre-connected to the metering pump electric drive, and the output is sequentially switched while counting the pulses corresponding to the metering pump moves circuits of the second switching device, one of which is pre-connected to the reset circuit of the first counter and pulses in the original state, and the second short pulse counter reset circuit in its initial state, is new to the initial state when the first reset pulse counter.

As a result, the method is simplified in comparison with the prototype by eliminating mathematical and logical operations for controlling the electric motor and regulating the injection volume of the pump, which also makes it possible to simplify the practical implementation of the method.

In the particular case of the implementation of the proposed method, the serial number of the output circuit of the first switching device, which is pre-connected to the metering pump electric drive, and the serial number of the output circuit of the second switching device, which is pre-connected to the reset circuit of the first pulse counter to the initial state, are mutually prime. In addition, in the particular case of the proposed method, the serial numbers of these output circuits are chosen equal to the numerator and denominator of one of the fractions belonging to the Farey sequence of order N, where N is the number of output circuits of each of the switching devices. This simplifies the claimed method, increases its reliability, reduces the complexity of practical implementation.

A device for implementing a method for dosing a reagent includes a pump driven by a reciprocating motion of an electric drive, a liquid flow meter with a pulse converter, a first pulse counter, the input of which is connected to the output of the pulse converter, and a second pulse counter. In this case, the first pulse counter is connected to the first switching device, the metering pump electric drive circuit is configured to connect to one of the output circuits of the first switching device, the second pulse counter is connected to the second switching device, the reset circuit of the first pulse counter is configured to connect to one of the output circuits of the second switching device, and the reset circuit of the second switching device is connected to the first output circuit of the first switching device Twa.

The device operates as follows. When a liquid moves through a pipeline, a liquid flow meter with a pulse converter generates a sequence of pulses corresponding to the measured amount of liquid. These pulses are fed to the input of the first pulse counter, which drives the first switching device connected to it. The first switching device sequentially commutes the output circuits, one of which is preliminarily (in preparation for operation) connected to the electric drive of the metering pump. When the first switching device closes this circuit, the electric metering pump starts to make reciprocating movements, each of which provides a direct and reverse stroke of the metering pump and the supply of a certain amount of reagent. Simultaneously with each stroke of the pump, a pulse is generated that is applied to the input of the second pulse counter, which drives the second switching device connected to it. The second switching device sequentially commutes the output circuits, one of which is previously (also in the process of preparation for operation) connected to the reset circuit of the first pulse counter. When the second switching device closes this circuit, the first counter and with it the first switching device returns to its original state. In this case, the first switching device opens the electric circuit of the metering pump, and the supply of reagent is stopped. After the first switching device returns to its original state, it will close the first output circuit connected to the reset circuit of the second pulse counter. Consequently, the second pulse counter also returns to its original state. After that, the process is automatically repeated.

Compared with the prototype, the first pulse counter is connected to the first switching device, the metering pump electric drive circuit is configured to connect to one of the output circuits of the first switching device, the second pulse counter is connected to the second switching device, the reset circuit of the first pulse counter is configured to connection to one of the output circuits of the second switching device, and the reset circuit of the second switching device is connected to the first output circuit of the first the switching device is new. This allows us to simplify the design and increase the reliability of the reagent dispensing device by eliminating the comparison unit and other arithmetic and logic devices, reduce the complexity and complexity of setting up the device, and improve the usability of the device for dispensing reagents.

In the particular case of the implementation of the inventive device as a first pulse counter connected to the first switching device and a second pulse counter connected to the second switching device, it contains electromagnetic step finders. Also, in special cases, the device comprises a wing flow meter, which is equipped with a contact chopper or a counting mechanism with sealed magnetically controlled contacts, as a liquid flow meter. In a particular case, the device comprises, as a pump driven by a reciprocating motion of an electric drive, a diaphragm pump. This provides the ability to manufacture the specified device on a simple and affordable element base.

Brief Description of the Drawings

Figure 1 shows a diagram of an embodiment of the claimed invention.

Figure 2 shows a diagram of a liquid flow meter with a pulse converter in the particular case, which, according to the applicant, is preferred for the implementation of the inventive device.

The following notation is used in the drawings:

1 - pipeline;

2 - liquid flow meter;

3 - pulse converter;

4 - tank for reagent;

5 - metering pump housing;

6 - membrane of the metering pump;

7 - dosing pump valves;

8 - electric metering pump, providing reciprocating motion;

9 - pulse generator corresponding to the strokes of the metering pump;

10 - coil of the electromagnet of the first pulse counter;

11 - the first pulse counter;

12 - contact field of the first switching device (the location of the contacts is shown conditionally; in reality, the contacts are arranged so that the brush of the switching device from the last contact switches further to the first, that is, switching occurs continuously);

13 is a continuous lamella used to return the first pulse counter to its original position;

14 - chopper used to return the first pulse counter to its original position;

15 - a device that allows you to connect the circuit of the electric drive 8 with one of the output circuits of the first switching device (for example, a switch);

16 - coil of the electromagnet of the second pulse counter;

17 - second pulse counter;

18 - contact field of the first switching device (the location of the contacts is shown conditionally, see the note to position 12);

19 is a continuous lamella used to return the second pulse counter to its original position;

20 is a chopper used to return the second pulse counter to its original position;

21 is a device that allows you to connect the reset circuit of the first pulse counter with one of the output circuits of the second switching device;

22 - galvanic battery;

23 - drive gear of the counting mechanism, which is equipped with a vane flow meter;

24 - gear counting tens of revolutions of the vane flow meter;

25 - tens transfer gears;

26 - gear counting hundreds of revolutions of the vane flow meter;

27 - gear account thousands of revolutions of the vane flow meter;

28 - one of the permanent magnets mounted on the gears of the counting mechanism;

29 - one of the sealed magnetically controlled contacts;

30 - a device that allows you to connect the circuit of the coil 10 with one of the sealed magnetically controlled contacts 29.

The implementation of the invention

The inventive method of dispensing a reagent can be carried out, in the simplest case, using a device, a diagram of which is shown in figure 1.

A device for implementing the water treatment method includes a pipeline 1, inside of which a vane flowmeter 2 is located. The shaft of the vane flowmeter 2 is connected to a pulse converter 3 using a stuffing, magnetic or other sealing device (not shown conventionally in the diagram). A contact breaker driven by a simple pulse converter driven by cam mechanism. In addition, the device contains a tank for reagent 4 connected to the pump. The pump has a housing 5 and a membrane 6, which form a closed cavity of variable volume. This cavity communicates with two valves 7, one of which communicates with the reservoir 4, and the other with the pipe 1. The membrane is connected to the actuator 8, capable of driving it in reciprocating motion. The electric drive is also connected to the contact sensor 9, the contacts of which are closed during each working stroke and open during the reverse stroke of the pump membrane. The reagent dispensing device includes a coil 10, which drives the first counter 11 and the first switching device having a contact field 12, a continuous lamella 13 and a chopper 14, which are structurally made as a single device - an electromagnetic step finder. The findings of the contact field 12 are connected to the contacts of the switch 15. The reagent dispensing device also includes a coil 16, which actuates the second pulse counter 17 and the second switching device having a contact field 18, a continuous lamella 19 and a chopper 20, which are also made in the form of an electromagnetic step finder . The findings of the contact field 18 are connected to the contacts of the switch 21. To bring the entire device into operation, it is equipped with a galvanic battery 22, consisting of 12 acid cans and giving a voltage of 24 volts (depending on operating conditions, the device can also be equipped with a rectifier).

The device operates as follows. When the fluid flow moves through the pipeline 1, an unbalanced torque acts on the impeller of the flowmeter 2, made in an asymmetric form, as a result, the flowmeter comes into rotation with a frequency proportional to the speed of the fluid flow. At each revolution of the flowmeter, the contacts of the cam interrupter 3 are closed. Each revolution of the flowmeter and each impulse of the interrupter 3 corresponds to a certain amount of fluid passing through the pipeline; denote this number V _IMP . At this moment, the circuit: the positive pole of the battery 22 - coil 10 - contacts of the chopper 3 - the negative pole of the battery 22 passes a current pulse, under the influence of which the readings of the counter 11 are increased by one and the step finder is activated, the brush of which switches to the next contact of the contact field 12. The process is repeated until the brush of the step finder does not reach the contact of the contact field 12, which is previously connected by the switch 15 to the electric drive 8. At this moment, the current begins to pass along pi: the positive pole of the battery 22 - contact 12 - the switch 15 - 8 drive - negative pole of the battery 22, whereby the drive starts driving the pump membrane 6 in reciprocation. With each working stroke of the membrane 6, the reagent from the cavity between the membrane 6 and the pump housing 5 through the valve 7 enters the pipeline. In addition, with each working stroke, the contacts of the sensor 9 are closed, generating an electric current pulse that flows through the circuit: the positive pole of the battery 22 - sensor 9 - coil 16 - the negative pole of the battery 22. As a result, the counter 17 increases by one and the step finder is triggered whose brush switches to the next contact of the contact field 18. The supply of reagent for one working stroke of the membrane, corresponding to one pulse of the sensor 9, will be determined by the design of the pump; denote this amount of reagent V _P.X. . During the reverse stroke of the membrane, the reagent will come from the reservoir 4 through the valve 7 into the cavity between the membrane 6 and the pump housing 5 under the influence of atmospheric pressure on the surface of the reagent in the reservoir 4. The process is repeated until the brush of the step finder reaches the contact of the contact field 18, which is pre-connected by a switch 21 to the negative of the battery 22. At this moment, the circuit closes: the positive pole of the battery 22 - coil 10 - continuous lamella 13 - breaker 14 - contact 18 - switch 21 - negative pole of the battery 22, whereby the first pulse counter reading increases by one, and the first switching device is switched to the next contact of the contact field 12. In this case, the electric power supply circuit 8 is opened and the reagent feed is stopped. At the same time, the chopper 14 opens the power circuit of the coil 10, and the electromagnet releases; in this case, the interrupter 14 closes, current is again supplied to the coil 10 and this process is repeated until the brush of the step finder leaves the continuous lamella 13, and this position corresponds to the zero reading of the counter 11 and the step finder switches to the first contact of the contact field 12. This contact, in turn, is connected to the breaker 20. The circuit closes: the positive pole of the battery 22 - the first contact of the contact field 12 - chopper 20 - continuous lamella 19 - coil 16 - the negative pole of the battery 22. As a result, the second count the pulse detector and the second switching device come into action, the frequency of which is provided by the action of the chopper 20, until the brush of the step finder comes off the continuous lamella 19, which corresponds to resetting the second pulse counter to its original position and switching the step finder to the first contact of the contact field 18. Thus, the entire circuit automatically returns to its original state. As the vane flowmeter 2 rotates further, the dosing process continues as described above.

Obviously, the operation of the described device is such that if the contact serial number of the contact field 12 connected to the switch 15 is n, and the contact serial number of the contact field 18 connected to the switch 21 is m, then after every n pulses of the chopper 3 (which corresponds to the volume of fluid flowing through line 1, nV _IMP ) the pump will make m working strokes (which corresponds to the supply of reagent mV _PX ), after which the process will be repeated. In this case, the proportion of the dosage of reagent K will be

where the values of V _IMP and V _{PX are} determined by the design of the device and are constant. Thus, the proportion of the dosage of reagent K is determined by the value of the fraction m / n. Since the values of m and n cannot exceed the number of output circuits of each step finder N, the largest number of possible values of the fraction m / n will be if the numbers m and n are chosen to be coprime, that is, that do not have common divisors other than one. In this case, the fraction m / n will be irreducible, otherwise you can reduce the values of m and n by dividing them by a common factor. The method of finding fractions with the irreducibility property was developed by M. Stern and A. Broco [4, p. 140]. For this, the starting ratios 0/1 and 1/0 are chosen and irreducible fractions are built by inserting the fraction (m + m ') / (n + n') between the fractions m / n and m '/ n', respectively. The construction is illustrated in Table 1, and the first four sequences of irreducible fractions have the form

You can see that at each step the number of fractions obtained increases rapidly, they are located strictly in ascending order, in addition, all fractions are irreducible. In this series, there will be any number expressed by the ratio of coprime integers a / b; as proved [4, p.142], it will occur no later than after a + b steps of inserting intermediate fractions. Since any rational number can be expressed as a / b, and the set of rational numbers is everywhere dense on the number line [5, pp. 59-60], the proposed method of dosing the reagent and the device for its implementation allow for the same values of V _IMP and V _P.X. to get the proportioning ratio arbitrarily close to any desired number by just setting the switches 15 and 21. Properly, the accuracy of approaching the desired proportioning is limited by the fact that the values m and n cannot exceed the number of output circuits of each step finder N. A subset of irreducible Stern – Broco fractions whose denominator does not exceed N, concluded between 0 and 1 and arranged in increasing order, is called the Farey sequence of order N [4, p.142]. Therefore, choosing the serial number of the output circuit of the first step finder n and the serial number of the output circuit of the second step finder m equal to the numerator and denominator of one of the fractions belonging to the Farey sequence of order N, we can get the best approximation to the desired proportion of dosing for a given value of N, determined by the design of the used step seekers. Irrational numbers are absent among the Stern – Broco fractions, as in the Farey sequences, but all rational numbers close to them are present [4, p. 146]. The representation of any, including the irrational number α in the form of a Stern – Broco fraction can be obtained by a simple binary search procedure [4, p. 147]. Thus, having asked any desired proportion of dosage K and knowing the design parameters of the device V _IMP and V _PX , it is easy to calculate the corresponding value from formula (1)

and then, using the binary search algorithm given in the source [4, p. 147], select the values of m and n such that m / n≈α, achieving the best possible degree of approximation.

Considering the sequences of fractions (2) obtained by the Stern - Broco method, one can notice that the values of the fractions in the middle of the interval (near the value 1/1) are closer to each other than at the edges. Therefore, the approximation of an arbitrary number α by irreducible fractions will converge to the exact value α with increasing N if α is a number of the order of unity, that is, between 0.5 = 1/2 and 5.0 = 5/1 [6 , p. 476]. In order for the inventive device to be able to provide a wide range of dosage proportions K at values of α of the order of unity, it is advisable to use a liquid flow meter with a pulse converter that allows you to change the liquid flow rate V _IMP corresponding to each pulse by 10 ⁱ times. A diagram of such a flow meter is shown in FIG. 2.

Vane flowmeter 2 rotates the drive gear 23, made with one tooth. The gear 23 is meshed with a ten-toothed gear for counting tens of revolutions 24, to which the single-tooth gear of transferring tens of 25 is rigidly connected. The gear of the counting of tens of 25 is meshed with a gear of counting hundreds of revolutions 26. The gear tooth 25 located on the shaft of gear 26 is engaged. with a ten-toothed gear, counting thousands of revolutions 27. One permanent magnet 28 is fixed on each of the gears. In the immediate vicinity of each gear, however, avoiding mechanical interference with s are reed contact 29. The reed contact is a small flask filled with an inert gas, by which the legs are soldered contacts made of a magnetically soft ferromagnetic alloy. When the permanent magnet 28 approaches the contacts 29, the latter are magnetized and attracted to each other, closing the circuit. When removing the permanent magnet 28, contacts 29 open the circuit. The strength of the magnets 28 and the position of the contacts 29 are selected so that with one revolution of each gear, the contacts located next to it are closed and opened exactly once. Thus, the contacts located next to the drive gear 23 are closed and opened once with each revolution of the wing flow meter 2; contacts located next to the gear of tens of 24 - once for every ten revolutions; and so on. In each pair of contacts 29, one contact is connected to the minus of the battery 22, and the other contact is connected to a device 30 (for example, a switch) that allows you to connect any of the contacts to the output of the coil 10. When using the flow meter shown in FIG. according to the formula

where i = 0, if the switch 30 is connected to the contact located at the gear of the counting unit of revolutions, i = 1 - at the counting gear of tens, i = 2 - at the counting gear of hundreds and i = 3 - at the counting gear of thousands of revolutions.

The proposed design of the flow meter seems to the author the most suitable for use in the inventive device, as it allows simple means with high accuracy to achieve any desired proportion of dosing in a wide range of values.

As a pump in the claimed design of the metering device, both a diaphragm and a piston pump can be used, as well as any other pump driven by the reciprocating movement of the electric drive. As pulse counters connected to switching devices, not only step finders can be used, but also, for example, counting and switching devices on decatrons.

Industrial applicability

The inventive method of dispensing a reagent and a device for its implementation can be applied in industry, in particular in heat engineering for water treatment processes, as well as in the chemical and oil industries. The method is simple, reliable and can be easily implemented and put into practice; during the setup process it does not require complex calculations and the participation of highly qualified specialists. Moreover, due to the use of the proposed method, it is possible to achieve any desired proportion of dosing with a high degree of accuracy. The device is also notable for its simplicity and reliability of construction; it is carried out on an affordable and inexpensive component base. The described device is easy to set up and operate, does not require complicated maintenance.

Information sources

1. Auth. testimonial. Czechoslovakia No. 210927, IPC G01F 11/00, publ. 01/29/1982. Způsob objemového dávkováni tekutin (Volumetric dosing method for liquids) / Nĕmeček J.

2. US Patent No. 6948914, IPC F04B 49/06, F04B 13/00, US Class 417 / 44.1, publ. 02/12/2004. Metering pump with an electric motor / Kragelund V., Byskov M.S., Jochumsen N.N.

3. German patent No. 10322404, IPC F04B 49/06, F04B 13/00, publ. 12/09/2004. Dosierpumpe und Verfahren zu deren Steuerung (Dosing pump and method for controlling it) / Stillhard O., Vos N., Scherf H., Mueller K.

4. Graham R., Knuth E., Patashnik O. Concrete Mathematics. A Foundation for Computer Science. 2-nd Edition. Reading: Addison-Wesley, 1998. Russian translation: Graham R., Knut D., Patashnik O. Concrete mathematics. The basis of computer science. Per. from English under the editorship of B.B.Pohodzeya and A.B.Khoduleva. M .: "World", 1998. Pp. 139-147. § 4.5. Mutual simplicity.

5. Kolmogorov A.P., Fomin S.V. Elements of function theory and functional analysis. 4th edition. M.: “Science”, 1976. P. 59-60. § 2. Convergence. Open and closed sets. A.3. Dense subsets.

6. Mathematical Encyclopedic Dictionary. Editor-in-chief Yu.V. Prokhorov. M .: "Soviet Encyclopedia", 1988. P. 476. Order.

Claims (10)

1. A method of dispensing a reagent using a metering pump driven by a reciprocating electric drive, including measuring a liquid flow rate, generating a sequence of electrical pulses corresponding to a measured amount of liquid, applying a sequence of pulses corresponding to a measured amount of liquid to an input of a first pulse counter, generating a sequence of electrical pulses corresponding to the strokes of the metering pump pulses corresponding to the strokes of the metering pump to the input of the second pulse counter, characterized in that simultaneously with the counting of the pulses corresponding to the measured amount of liquid, the output circuits of the first switching device are sequentially switched, one of which is pre-connected to the metering pump electric drive, simultaneously with the pulse counting corresponding to the strokes of the metering pump, carry out sequential switching of the output circuits of the second switching device a, one of which is preliminarily connected to the reset circuit of the first pulse counter to the initial state, and when the first pulse counter is reset, the circuit for resetting the second pulse counter to the initial state is closed. 2. The method according to claim 1, characterized in that the serial number of the output circuit of the first switching device, which is pre-connected to the electric metering pump, and the serial number of the output circuit of the second switching device, which is pre-connected to the reset circuit of the first pulse counter, are coprime numbers. 3. The method according to claim 2, characterized in that the serial number of the output circuit of the first switching device, which is pre-connected to the metering pump electric drive, and the serial number of the output circuit of the second switching device, which is pre-connected to the reset circuit of the first pulse counter, choose equal to the numerator and denominator of one of the fractions belonging to the Farey sequence of order N, where N is the number of output circuits of each of the switching devices. 4. The device for implementing the method according to claim 1, comprising a pump driven by a reciprocating motion of the electric drive, a liquid flow meter with a pulse converter, a first pulse counter, the input of which is connected to the output of the pulse converter, a second pulse counter, characterized in that the first pulse counter is connected to the first switching device, the electric circuit of the metering pump is configured to connect to one of the output circuits of the first switching device a, the second pulse counter is connected to the second switching device, the reset circuit of the first pulse counter is configured to connect to one of the output circuits of the second switching device, and the reset circuit of the second switching device is connected to the first output circuit of the first switching device. 5. The device according to claim 4, characterized in that as the first pulse counter connected to the first switching device, and the second pulse counter connected to the second switching device, it contains electromagnetic step finders. 6. The device according to claim 4, characterized in that as a liquid flow meter it contains a vane flow meter. 7. The device according to claim 6, characterized in that the vane flowmeter is equipped with a contact chopper. 8. The device according to claim 6, characterized in that the vane flowmeter is equipped with a counting mechanism with sealed magnetically controlled contacts. 9. The device according to any one of paragraphs.4-8, characterized in that as a pump driven by the reciprocating movement of the electric drive, it contains a diaphragm pump. 10. The device according to any one of paragraphs.4-8, characterized in that as a pump driven by the reciprocating movement of the electric drive, it contains a piston pump.

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