RU2337320C1 - Water meter - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: meter includes impeller with two magnets mounted on its opposite ends inside case cavity, Hall sensor mounted on external case side over the magnet travel path during impeller rotation, pulse generator unit for Hall sensor, control and computation unit based on microcontroller, scale factor optimization unit, timer, LCD indicator, power source, computer connection unit.

EFFECT: increased measuring precision, reduced energy consumption, and operation time account.

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Description

The invention relates to instrumentation and can be used to measure the amount of water. The device according to this invention can be used as a household water meter apartment type.

A well-known water and gas meter (US Pat. RU No. 2187076, G01F 1/115), containing a primary sensing element in the form of a turbine or impeller with magnets mounted on its blades, mounted in a pipe in which the medium is flowing, and a secondary element, including a counting mechanism with a magnet located on the surface of the pipe with the primary element, and in the primary element the magnets are mounted on two blades, in different planes, and in the secondary element there is one permanent magnet on the shelf, the ends of which contain teeth, one of which is oriented to the wall of the tooth profile of the gear connected mechanically with the counting mechanism, and the second tooth of the shelf is oriented to the top of the adjacent gear tooth.

The disadvantage of the counter is the limited ability to change the conversion factor and adjust the relative error due to the presence of mechanical reduction devices. Another disadvantage of the known meter is that the mechanical meter has a large static and dynamic moment of resistance, which worsens the sensitivity threshold and leads to an increase in the lower limit of the range of measured flow rates.

A counter device for water and gas flow meters is known (Pat. RU No. 2131115, G01F 1/075), comprising an information pickup device, an electronic device for converting the speed of a sensitive element to the amount of a substance passed through a meter with a sensor power supply system, and a transmission coefficient optimization unit depending on the current flow rate and an indication device, moreover, the information acquisition device is made in the form of two diametrically installed through a diamagnetic partition diametrically relative to the axis of rotation m hollows of the sensor element of the Hall sensors, the interaction surfaces of which are identical with the magnet of the sensor and the outputs of the sensors are combined, the sensors are electrically connected to a power system that generates power pulses alternately to one of the Hall sensors by the command of the previous one, while the display device is equipped with a switching circuit only for a fixed reading time.

One of the disadvantages of the known device is the low power consumption, because even with pulsed power, the Hall sensors consume significant current. In the presence of two Hall sensors, they make the main contribution to the consumption of the entire device and consume such a large current that it becomes necessary to use large capacity batteries (batteries), and therefore leads to a rise in the cost of the counting device, which is a significant negative factor for a household appliance. Another disadvantage is the lack of funds in the device structure for inputting conversion factors into the transmission coefficient optimization unit, determined by the calibration results of the calculating device. And another disadvantage of the known calculating device is the insufficiently wide functionality.

Of the analogues, the closest in technical essence is a device for measuring fluid flow (US Pat. RU No. 2152128, G01F 1/06, G01F 1/075), comprising a sensor housing having an inlet and outlet, an impeller mounted on an axis in the housing cavity at least one magnet installed in the upper part of the impeller, a counting device enclosed in a housing that contains a counting reed switch interacting with the impeller magnet and connected to a computing device made in the form of a microcircuit mounted on a printed circuit ate, which is associated with a digital LCD display, a power source, for controlling the counting device on the PCB contact pads are made, to which access the housing hole provided for the counting device.

The disadvantage of this device is its low reliability and wear resistance, since it contains a reed switch as a sensor for the number of revolutions of the impeller. It is known that the reed switch has a finite number of operations, which is usually about 10 ⁶ -10 ⁷ . At a frequency of 10 Hz (the maximum rotational speed of the impeller is usually about 50-60 Hz) and when the device operates no more than 1 hour per day, the reed switch will develop its life in less than 1 year, while the service life of metering devices (water, gas meters etc.) should be at least 8-10 years.

Another significant drawback of the device is its high power consumption, since the reed switch consumes a current of the order of several mA, and it cannot be powered by a battery due to high consumption. At the same time, modern energy metering devices are designed, as a rule, with battery power, which avoids the problems associated with the presence of industrial interference from the AC mains and ensures independence from the network.

The technical result of the claimed invention is to increase the accuracy of metering and expand the functionality of the meter counter water metering while reducing energy consumption.

This result is achieved by the fact that in the meter for water metering, which includes a sensor housing with inlet and outlet nozzles, an impeller mounted on an axis in the housing cavity, magnets mounted in the upper part of the impeller, diametrically relative to its axis, a control and calculation unit based on a microcontroller , a liquid crystal indicator, an electric power supply, an additional Hall sensor is installed, which is installed on the outer part of the water meter casing above the path of the magnets when the impeller rotates, optimizer conversion coefficient, timer, pulse power generation unit for the Hall sensor, a communication unit with a computer, the first input of the Hall sensor connected to a common bus of the meter's electronic circuit for water metering, the second input of the Hall sensor connected to the output of the pulse power generation unit, and the sensor output The hall is connected to the first input of the control and calculation unit based on the microcontroller, the first output of which is connected to the input of the liquid crystal indicator, the second input of the control and calculation unit based on the microcon the controller is connected to the positive terminal of the power supply, the negative terminal of which is connected to the common bus of the electronic circuit of the meter for water metering, and all other elements of the electronic circuit of the water meter are also powered by the power supply, the third input of the control and calculation unit based on the microcontroller is connected to the output of the optimization unit conversion factors, the input of which is connected to the second output of the control unit and calculations based on the microcontroller, the fourth input of which is connected to the first output ohm timer, a second output connected to the input of the pulse power generating unit to the Hall sensor, and a fifth control input calculation block based on a microcontroller connected to the output of the coupling unit with a computer, whose input is connected to the third output control unit and calculating on the basis of the microcontroller.

The introduction of a correction unit for the conversion coefficient allows to increase the accuracy of measuring the water flow rate by dividing the conversion characteristics of the impeller speed into flow rate into linear sections and using for each section an individual conversion factor for the pulses from the impeller to the amount of water.

The introduction of a unit for the formation of a pulse power supply for the Hall sensor allows reducing the energy consumption of the meter for water accounting.

The introduction of a timer allows you to expand the functionality of a water meter for water metering, providing metering of the meter’s operating time.

The communication unit with the computer also allows you to expand the functionality of the water meter. It makes it possible to transfer the meter readings to an external system, as well as to enter into the meter data obtained by the results of its calibration at the stand.

The drawing shows a block diagram of a meter for metering water.

The water meter includes a sensor housing with inlet and outlet nozzles 1, an impeller 2 mounted on an axis 3 in the cavity of the housing 1, the first 4 and second 5 magnets installed in the upper part of the impeller 2, diametrically relative to its axis, a Hall sensor 6 installed on the outer part of the body 1 of the water meter above the path of the magnets during their rotation, the control and calculation unit based on the microcontroller 7 (hereinafter MK), a liquid crystal indicator 8, a power supply (battery) 9, a coefficient optimization unit p 10, a timer 11, a pulse power generating unit for the Hall sensor 12, a communication unit with a computer 13, the first input of the Hall sensor 6 connected to a common bus ("ground") of the electronic circuit of the meter for water accounting, the second input of the Hall sensor 6 (positive power output) is connected to the output of the pulse power generating unit 12, and the output of the Hall sensor 6 is connected to the first input of the control and calculation unit based on the microcontroller 7, the first output of which is connected to the input of the liquid crystal indicator 8, the second input of the control unit Based on the microcontroller 7, calculations and calculations are connected to the positive terminal of the power supply 9, the negative terminal of which is connected to the common bus of the meter’s electronic circuit for water metering, and all other elements of the electronic circuit are also powered from the power supply (batteries), the third input of the control and calculation unit based on the microcontroller 7 is connected to the output of the unit for optimizing the conversion factors 10, the input of which is connected to the second output of the control and calculation unit based on the microcontroller 7, the fourth the stroke of which is connected to the first output of the timer 11, the second output of which is connected to the input of the pulse power generation unit for the Hall sensor 12, the fifth input of the control and calculation unit based on the microcontroller 7 is connected to the output of the communication unit with a computer 13, the input of which is connected to the third output of the block microcontroller based control and computing 13.

The meter for accounting water works as follows.

Water passing through the meter body 1 acts on the impeller 2, and the force of influence is proportional to the frequency of rotation of the impeller and, therefore, the flow rate of water.

When the impeller 2 rotates, magnets 4 and 5 installed in the upper part of the impeller 2 periodically pass under the Hall sensor 6, and at the output of the Hall sensor 6, a pulse is generated that is fed to the first input of the control and calculation unit based on MK 7.

From the second output of the timer 11, pulses with a frequency equal to four times the maximum rotational speed of the impeller 2 (approximately 200 Hz) corresponding to the maximum flow rate are received at the input of the pulsed power supply unit for the Hall sensor 12. The pulse power generation unit for Hall sensors 12 along the leading edges of these pulses generates pulses of the smallest possible duration sufficient to respond to the power supply to the Hall sensor 6 and to receive a signal from its output.

Upon receipt of one or more pulses (depending on the speed of rotation of the impeller 2 during the passage of the magnet under the Hall sensor 6) from the output of the Hall sensor 6 to the first input of the control and calculation unit on the basis of MK 7, an impulse is generated in this block, indicating the passage of half of the impeller revolution.

When each such pulse is generated, the control and calculation unit based on MK 7 determines the flow rate in time between two adjacent pulses, measured by a timer, and, depending on the flow rate, extracts from the conversion factor optimization block 10 the value of the conversion factor of the pulses into the amount of water corresponding to the current flow rate .

The block of optimization of conversion factors 10 contains a set of conversion factors corresponding to the linear sections of the graph of the dependence of water flow on the rotational speed of the impeller 2.

After extracting the conversion factor from the conversion factor optimization unit 10, the control unit and calculation on the basis of MK 7 adds to the total amount of water accumulated in it the amount of water determined by the corresponding current consumption conversion factor corresponding to one pulse generated in it per half revolution of the impeller 2.

The timer 11 counts the operating time of the gas meter. From the first output of timer 11, the current time value is transmitted to the fourth input of the control and calculation unit based on MK 7, which, at predetermined time intervals (for example, once a day or upon request from a computer), transfers the accumulated total amount of water to the communication unit with computer 13 measured by the meter for water accounting, as well as the total time of the meter.

The measured total values of the amount of water and the operating time of the meter for metering water are also output to the liquid crystal indicator 8 at predetermined time intervals (for example, once every five seconds).

The present invention improves the accuracy of measuring the flow rate and amount of water by introducing a unit for optimizing conversion factors 10. For each specific flow sensor, including a housing with inlet and outlet pipes 1, an impeller 2 mounted on an axis 3 in the cavity of the housing 1, the Hall sensor 6, on the calibration stand, "spilling" the sensor with water, remove the dependence of the flow rate on the impeller speed, which is non-linear. Then, dividing the dependence graph into linear sections, for each section, an individual coefficient for converting the frequency of the sensor output signal to the water flow rate is determined. These values are entered into the unit for optimizing conversion factors 10 from a personal computer (PC) through the communication unit with computer 13 and the control and calculation unit based on MK 7. Further, these coefficients are used by the meter to account for water during operation. The introduction of a block of optimization of conversion factors 10 allows to reduce the error in the measurement of flow to 0.1-0.2%.

The measurement accuracy in comparison with known analogues is also enhanced by the use of two magnets mounted in the upper part of the impeller.

Reducing energy consumption is achieved through the use of a pulsed power supply to the Hall sensor 6. This method allows to reduce energy consumption by three orders of magnitude, up to 3 ÷ 4 μA compared to the prototype and two times compared to the analogue by using only one Hall sensor, without loss of accuracy, since two magnets are used in the primary converter (impeller 2).

The introduction of a timer 11 and a communication unit with a computer 13 expands the functionality of the meter for water metering, since it allows fulfilling the requirements of metering the device’s operating time and transferring measured data to external systems presented to modern energy metering devices.

Claims (1)

Water meter including a sensor housing with inlet and outlet nozzles, an impeller mounted on an axis in the housing cavity, first and second magnets mounted diametrically relative to its axis in the upper part of the impeller, a microcontroller-based control and calculation unit, a liquid crystal indicator, a source power supply, characterized in that it additionally includes a Hall sensor mounted on the outside of the water meter casing above the path of the magnets when the impeller rotates, the unit is optimized conversion coefficient, timer, pulse power generation unit for the Hall sensor, a communication unit with a computer, the first input of the Hall sensor connected to a common bus of the meter's electronic circuit for water metering, the second input of the Hall sensor connected to the output of the pulse power generation unit, and the sensor output The hall is connected to the first input of the control and calculation unit based on the microcontroller, the first output of which is connected to the input of the liquid crystal indicator, the second input of the control and calculation unit based on the micro the controller is connected to the positive terminal of the power supply, the negative terminal of which is connected to the common bus of the electronic circuit of the meter for water metering, and all other elements of the electronic circuit of the water meter are also powered by the power supply, the third input of the control and calculation unit based on the microcontroller is connected to the output of the optimization unit conversion factors, the input of which is connected to the second output of the control unit and calculations based on the microcontroller, the fourth input of which is connected to the first output a timer house, the second output of which is connected to the input of the pulse power generation unit for the Hall sensor, the fifth input of the control and calculation unit based on the microcontroller is connected to the output of the communication unit with a computer, the input of which is connected to the third output of the control and calculation unit based on the microcontroller.