RU175419U1 - GAS FLOW METER - Google Patents

Abstract

The utility model relates to the field of measurement technology and can be used in systems for measuring gaseous media. The gas flow meter comprises a flow measuring tube with an inlet chamber with a fan controlled by a drive and an inlet with a drive controlled by a turbine located inside the main channel and an inlet cowl of the fan together with the inlet cowl of the turbine made by a tapering ring nozzle and an outlet chamber connected by a channel reverse with a fan inlet chamber, and automatic gas flow calculation. The technical result - the location of the turbine with a controlled drive in the main channel of the meter, expanding the zone of linear characteristics, reducing the error of flow measurement, using the compensation method of measurement. 2 ill.

Description

The utility model relates to the field of measurement technology and can be used in systems for measuring gaseous media.

A known medium flow meter (RU 2572461 C2, 01/10/2016), in which part of the stream is returned through an auxiliary flow meter to the main channel to lower the sensitivity threshold. The disadvantage of this device is the presence in the measuring circuit of an additional flow meter, which complicates the measurement procedure. An additional device always increases the cost of operation associated with its certification, increases the set of equipment, reduces the total resource of the meter.

A known turbine gas flow meter (RU 172725 U1, 07/21/2017), which contains a measuring pipe with an inlet chamber with a fan and a turbine located inside the main channel inside the stream in the main channel. A disadvantage of the known flow meter in the absence of a controlled turbine drive, which does not allow the interaction between the fan and the turbine when measuring flow in the main section of the gas flow measurement, the inability to adjust the turbine speed to reduce the measurement error.

The technical result is the location of the turbine with a controlled drive in the main channel of the meter, expanding the zone of linear characteristics, reducing the error of flow measurement, using the compensation method of measurement.

The technical result is achieved by the fact that the proposed gas flow meter according to the model contains a flow measuring tube with an inlet chamber with a fan controlled by a drive and an inlet with a drive controlled by a turbine located inside the main channel and an outlet cowl of the fan together with the turbine inlet a tapering ring nozzle, an exit chamber connected by a reverse channel to the fan inlet chamber, and automatic gas flow calculation.

In FIG. Figure 1 shows the design of the model in longitudinal AB along the flow and transverse SS sections.

In FIG. 2 shows the static characteristic of the model in the coordinates of the frequency-flow rate расход = F (Q).

The principle of operation of a gas flow meter is based on the interaction of a moving gas stream with a fan (fan impeller) with a drive and with a turbine (turbine wheel impeller) with its drive located in the measuring tube. Using an impeller, the axial velocity of the gas stream is converted to the angular velocity of rotation. The rotational speed of the impeller is proportional to the volumetric flow rate of the gas, and the number of revolutions of the impeller is proportional to the volume of gas passed through the measuring transducer.

The gas flow meter (Fig. 1) contains a flow measuring tube 1 with an inlet chamber 3 located inside the main channel 2, an inlet 5 of the fan 4, driven by an actuator, an inlet 6 of a turbine 7, controlled by its own drive, an outlet chamber 8 connected by a channel 9 reverse with input 5 of fan 4 and through input 6 with turbine 7, confuser nozzle 10 and automation 11 and 18 of measuring and calculating gas flow.

The automation of measurement and calculation of gas flow in the form of a block is mounted directly on the measuring tube 1 and operates on 2 measurement and calculation algorithms.

The entire measurement range (Fig. 2), as in the prototype, is divided into two parts. The boundary of the division of the measurement parts (point A) is determined by the frequency of the generator 12. In the first part to point A, fan 4 operates with a reverse flow (line Q ₂ ) - the flow measurement is calculated (automatic circuit 11 operates) by changing the difference in the arrival frequencies of the main flow Q and the decrease of the reverse flow Q ₂ , in the second part, the fan 4 maintains a zero pressure drop across the turbine 7 by generating a control signal to the drive of the turbine 7 and reducing the loss of static pressure.

Zero pressure drop is used in the most significant flow rate in the main measurement area, significant in reducing the measurement error at high flow rates.

In the first part of the range, when the flowmeter works in the field of measuring lowered flow, the first algorithm works according to the scheme 11, consisting of an adder 14 - this is a device for comparing rotation speed signals with a frequency ƒ _t received from a turbine 7 coming through terminals 16, and the signal of the own 12 electric generator _{Э constEG} to correct the signal to the impeller drive 4 through terminals 15. The flow indicator 13 Q is common when both algorithms are running.

In the first part of the range

flow rate Q ₂ varies from Q _2max = Q _tn to Q ₂ = 0, in frequency from ƒ _2max = ƒ _tn to ƒ ₂ = 0,

flow rate Q varies from Q _tn = 0 (20 l / h) to Q _t = Q _eg (100 l / h), in frequency from ƒ _tn to ƒ _t = ƒ _{const EG} ,

the flow rate Q ₁ = Q ₂ + Q = const does not change, the frequency does not change ƒ ₁ = ƒ ₂ + ƒ _t .

When measuring in the first part: increase the reverse flow Q ₂ (ƒ ₂ ) while decreasing the measured flow Q (ƒ _t ) to the agreed selected lower limit value and reduce the value Q ₂ (ƒ ₂ ) to zero as the flow Q increases to the selected upper value the limit of the first part of the range.

In the second part of the range, the generator 12 is turned off. Automation works according to the second algorithm - circuit 18, consisting of a zero-organ 17 of the rotational speed of the fan 4 and the adder 14, the output signal of which is transmitted to the indicator 13.

, измеренный турбиной 7 при работе вентилятора 4, линия Q₂ - изменение расхода реверса Q₂ при подаче в камеру 6 и турбину 7 от вентилятора 4. В этом диапазоне измерения расхода до т. А индикатор 13 фиксирует расход газа по формуле Q=Q₁-Q₂ или по частоте ƒ_т=ƒ₁-ƒ₂.In FIG. 2 line Q ₁ characterizes the flow

measured by turbine 7 during operation of fan 4, line Q ₂ is the change in the flow rate of reverse Q ₂ when supplied to chamber 6 and turbine 7 from fan 4. In this range of flow measurement to t. A indicator 13 fixes the gas flow rate by the formula Q = Q ₁ -Q ₂ or in frequency ƒ _t = ƒ ₁ -ƒ ₂ .

To form a flow and reduce hydraulic resistance to gas flow, the impellers of the fan 4 and turbine 6 are enclosed in aerodynamic fairings. The exhaust fan cowl together with the turbine inlet cowl constructively constitute a tapering ring nozzle in which the main stream 2 increases the speed, static pressure decreases in the chamber 6 and the draft and flow rate Q _{2 of the} fan 4 increase. The tapering (confuser) ring nozzle 10 allows increasing the Reynolds number Re, characterizing the flow of the measured flow, and expands the zone of linear characteristics (P. P. Kremlevsky. Flow meters and counters of the amount of substances. Ref. Book One \ Polytechnic. St.P. 2002 . \ P. 302). The model uses two blowers 4 and 7 to simplify setup and operation.

The fan 4 is turned on by the gas consumer by an external command by the on / off button on the adder 14. The flow Q _{2 of the} fan 4 flows along the ring of channels formed by the following structural elements (Fig. 1): camera 8, channel 9 of the reverse flow, camera 5 with fan 4, camera 6, with a turbine 7 located therein and again camera 8.

In the absence of a pressure drop in the gas network, the turbine 7 measures only the flow rate of the fan 4. At the same time, the insensitivity threshold of the turbine 7 is overcome and a stable initial frequency ƒ _t of turbine rotation is achieved (Fig. 2). Through the rotation sensor of the turbine 7 and terminal 16, the frequency ƒ _{t of the} turbine 7 is compared in magnitude with the given frequency ƒ _{const EEG of the} generator 12 of the automation circuit 11 and the resulting difference in these frequencies ƒ _max = ƒ _t- ƒ const _EEG is fixed as corresponding to the gas flow Q _min = 0, starting from which the flow rate Q is measured by the turbine 7.

In the presence of a pressure drop in the network, a total flow Q ₁ = Q + Q _{2 is formed} due to the connection of the reverse flow Q ₂ through the fan 4, and the flow Q of the main channel 2 passes into the chamber 3 and to the input 6 and through the turbine 7 to the exit chamber 8 to to the consumer. The value of Q ₁ is measured by the initial frequency of rotation ƒ _{t of the} turbine 7, formed by the reverse flow Q ₂ in the absence of flow Q. An increase in the frequency of rotation of the turbine by Δƒ is transmitted to the adder 14 with subsequent output to the indicator 15. In the chamber 8, the output from the total stream Q ₁ is allocated the reverse flow Q ₂ and from the output of the flow meter, a flow of magnitude Q reaches the consumer. Isolation of the reverse flow Q ₂ occurs due to partial rarefaction in the chamber 8, formed by the thrust (evacuation, suction) during rotation of the fan 4 to the extent that is determined by the difference Δ _max = ƒ _t -ƒ _{constEG of} the turbine 7 frequency and the frequency set by the generator 14 ƒ _constEG in the first part of the flow measurement.

With a gradual increase in the flow rate Q in the main channel 2, the rotational speed of the turbine 7 increases and, in terms of Δƒ = ƒ _t -ƒ _{const, the EH} adder 14 gives a command to drive the impeller of fan 4 to reduce the flow rate of Q ₂ . At the same time, a change in the frequency Δƒ, which is inversely proportional to ΔQ ₂ , is recorded by indicator 15 as the gas flow Q actually measured by the meter. In this case, after the subtraction procedure, the gas flow Q at the outlet of the chamber 8, which entered the load, is considered equal in magnitude to the flow entering the main channel 2 and measured with some error ς, depending on the stability of the static frequency-flow fan characteristic and negative feedback in the adder 14. When you change the value of the flow Q inversely changes the magnitude of the flow of the reverse Q ₂ . The flow Q ₂ developed by the fan 4 is controlled by the adder 14.

As the flow rate Q increases, the flow rate Q ₂ , developed by fan 4, decreases to zero, and the fan stops working when Δ, = 0, and the generator 12 is turned off from operation. This moment is fixed on point A on the characteristic (Fig. 2) and the second part characteristics when measuring the flow rate Q after passing t. A. When measuring, the compensation method with zero differential pressure is used. This makes it possible to equalize the flow rate Q in the flow pipe 1 along the main channel 2 and the flow rate Q ₁ passing through the turbine 7. In this balanced state _{, the} rotational speed ƒ _t of the turbine 7 will “ideally” measure the flow rate Q. The compensation method with zero differential pressure reduces the measurement error expense. When measuring the flow rate of a turbine rotating only under the pressure of the flow Q, the error is always higher due to leaks through the turbine, changes in viscosity and dynamic speed errors when changing the flow regime.

. Измерением частоты вращения турбины 7, сигнал которой непосредственно проходит через устройство 18 на индикатор 13, фиксируется измеряемый расход во втором диапазоне. Вентилятор 4 находится в пассивном режиме и не управляется своим приводом, а управляется расходом Q₂ реверса. В классической схеме измерения расхода нулевой перепад контролируется датчиком перепада давления непосредственно на измерителе. В данной схеме измерения нулевой (близкий к нулю) перепад давления контролируется расходом газа между камерами 6 и 8, т.е. отсутствие расхода между сечениями подтверждает отсутствие перепада давления между ними

.In the second part of the range, the fan 4 operates as a zero indicator of the pressure difference between the chambers 6 and 8 when measuring the flow rate Q of the flow of the main channel 2 with a turbine 7 at a certain amount of reverse flow

. By measuring the speed of the turbine 7, the signal of which directly passes through the device 18 to the indicator 13, the measured flow rate is fixed in the second range. Fan 4 is in passive mode and is not controlled by its drive, but is controlled by the flow rate of Q ₂ reverse. In the classical flow measurement scheme, the zero differential is controlled directly by the differential pressure sensor on the meter. In this measurement scheme, the zero (close to zero) pressure drop is controlled by the gas flow between chambers 6 and 8, i.e. the absence of flow between sections confirms the absence of a pressure drop between them

.

передается через автоматику, работающей по алгоритму 18, турбине 7 и изменяет уже ее частоту вращения (подкручивая или замедляя). Корректировкой скорости турбины устраняются потери статического давления основного потока Q, типа потерь на завихрение потока, на трение, потери на входе и выходе из турбины, неучтенный расход при прохождении сквозь турбину 7 и др. Сигнал величины скорости вращения вентилятора 4, как нуль-органа, передается в блок 17 и через сумматор 14 на привод турбины 7 для поддержания скорости ее вращения потока для сохранения равенства Q₁=Q и замера расхода.If there is a certain speed of rotation of the fan impeller 4, the signal deviation of its speed from the signal

It is transmitted through automation working according to algorithm 18 to turbine 7 and already changes its rotation frequency (twisting or slowing down). By adjusting the speed of the turbine, the static pressure loss of the main flow Q, such as losses due to swirling of the flow, friction, losses at the inlet and outlet of the turbine, unaccounted flow rate when passing through the turbine 7, etc. is eliminated. The signal of the fan speed 4, as a zero-organ, transmitted to the block 17 and through the adder 14 to the drive of the turbine 7 to maintain the speed of its rotation of the flow to maintain the equality of Q ₁ = Q and metering flow.

между точками 6 и 8.With a decrease in flow Q, the reverse flow receives the opposite direction, increasing the pressure behind the turbine 7 and increasing the channel resistance behind the turbine. This reduces the speed of rotation of the turbine 7 to equalize the flow rate Q ₁ = Q, and reduce (to contain) the flow of reverse Q ₂ to the state Q ₂ = 0 and differential pressure

between points 6 and 8.

An additional correction of the measured flow rate is possible using the previously obtained characteristics Q ₂ = F (Q) stored in the library of the automation computing unit 19.

на выбранном уровне необходимо для отсчета показаний Δƒ=ƒ_т-ƒ_constЭГ приращения расхода ΔQ, подаваемых на индикатор 13. Таким образом, измерение начинается с произвольно заданной начальной величины Q₁=20 л/ч, которую можно выбрать и менее, но это определяется порогом чувствительности вентилятора 4. При выбранных начальных условиях расход Q<20 л/ч не измеряется. После т. А измерение ведется по линии Q с погрешностью, определяемой турбиной 7, как турбиной, включенной в работу с корректировкой по «нулевому» перепаду давления. Предложенная модель позволяет снизить порог чувствительности расходомера, тем самым расширить диапазон измерения расхода и уменьшить погрешность измерения расхода в двух частях диапазона до и после т. А.A practical example. The measuring operation of the fan 4 (Fig. 2, line Q ₂ ) and the reverse flow Q ₂ begins with a conditional zero, for example, Q ₂₀ = 20 l / h is assigned. The flow rate Q _{1 is} maintained constant (line Q ₁ ) along the main channel 2 through the turbine 7, and equal, for example, 100 l / h (t. A). In the first part, maintaining flow

at the selected level, it is necessary to read the readings Δƒ = ƒ _t -ƒ _{constEG of} the flow increment ΔQ supplied to the indicator 13. Thus, the measurement begins with an arbitrarily set initial value Q ₁ = 20 l / h, which can be chosen even less, but this is determined threshold sensitivity of the fan 4. At the selected initial conditions, the flow rate Q <20 l / h is not measured. After t. A, the measurement is carried out along the Q line with an error determined by the turbine 7 as a turbine included in the work with adjustment for the “zero” pressure drop. The proposed model allows to reduce the sensitivity threshold of the flow meter, thereby expanding the range of flow measurement and reducing the error of flow measurement in two parts of the range before and after t. A.

Claims (1)

A gas flow meter, characterized in that it contains a flowing measuring tube with an inlet chamber with a fan located inside the main channel and controlled by a drive and an inlet with a turbine driven by its own drive; output connected by the reverse channel to the fan inlet chamber, and automatic gas flow calculation.

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