RU2531032C1 - Method to measure medium flow - Google Patents

Abstract

FIELD: measurement equipment.

SUBSTANCE: method to measure medium flow, in which the main flow is summed with the back flow, the summary flow is sent via the main flow meter, measured, then divided into two flows, one of which is considered equal to the inlet one and is sent to the load, the other is considered the back flow, measured by its flow meter and subtracted from the summary flow. At the same time the entire range of measurement is divided into two parts - the first part of measurement with the back flow, the second part of measurement - without the back flow. In the first part of the range the back flow is forcedly sent to the main flow for summation, its value is changed inversely to the value of the main flow. In the second part of the range the flow rate of the main flow is measured by the main flow meter without the back flow. Besides, using the invention, they set the relation between the back flow and the main flow as proportionate and inverse.

EFFECT: increased range of flow measurement.

4 cl, 1 dwg

Description

The invention relates to the field of measuring equipment and can be used in systems for measuring gaseous and fluid media, as well as in commercial calculations.

A known method of measuring the flow rate of the medium, in which the medium is supplied from the highway through a pump, flowmeter and workload (Kremlevsky P.P. Flow meters and quantity counters. Reference // L., Engineering, 1989, 702 S.). A disadvantage of the known methods is the location of the measuring device in a series of flow rate consumption devices, which does not provide sufficient accuracy of the flow measurement.

A known method of measuring a jet flow meter (RU 1295230 A1, 03/07/1987) with an insufficient sensitivity zone, which limits the working area and the measuring range. The disadvantage of this method is the inevitability of the existence of conflicting requirements and the impossibility of overcoming them when implementing only one physics of the flow of the medium. These requirements are reduced to two parameters: the minimum measured flow rate and the maximum allowable pressure drop across the flowmeter at the maximum point in the range.

A known method of measuring fluid flow (RU 2157967 C2, 05.21.1998), adopted as a prototype. A part of the medium flow after the main flow meter is returned through the auxiliary flow meter and the restrictive throttle to the line in front of the pump, and the flow rate for the working load is determined as the difference in flow rates through the main and auxiliary flow meters. This technique allows you to shift the measuring area of the main flow meter to the required range with lowering the lower boundary of the measurement.

The disadvantages of this method is the requirement that the composition of the measuring complex pressure device (pump) installed in the highway, because without it, the complex is not operational.

In addition, the pump must comply with the main flow rate, which is associated with the fulfillment of other design requirements: increased dimensions, weight, resource, price, etc.

In addition, with this method, there is a functional relationship between the main flow meter and its load, which makes it necessary to coordinate their parameters with each other. Otherwise, the operation of the complex is impossible if the load absorbs the main flow. In addition, the second measuring device (auxiliary flowmeter) must have a measurement error that is obviously less, which burdens the complex with additional measurement technology of a different range with a forced calibration, price, dimensions, weight, etc.

In addition, the main and auxiliary flowmeters continuously operate in the full measurement range, which reduces the resource of the measuring part of the complex located in the return line of the part of the stream, which is intended only for expansion in the lower part of the range, and should not function when measuring in the accepted range.

In addition, the measurement range is shifted in the presence of a return flow line, which lowers the sensitivity threshold and together with it reduces the upper limit of the measurement, which significantly narrows the measurement range and suggests choosing a main flow meter with a margin at the upper limit.

In addition, the flows of the main pipeline and the return are interdependent. There is no such state when one stream is constant in magnitude and the other stream changes and can be independent.

In addition, when analyzing the well-known complex as a measuring device, it was shown that the links of the measuring circuit (two flowmeters) are connected in a counter-parallel connection with positive feedback, i.e. with an increase in flow in the main pipeline, the return flow through the auxiliary flow meter simultaneously increases. Such a compound in the complex significantly increases the measurement error not only in the zone of lowering the range to the threshold of sensitivity, but also after, because in this case, the errors of the links are summarized (D. Braslavsky. Instruments and sensors of aircraft. M., Mechanical Engineering, 1970, p. 108).

In addition, in the known measurement complex, the characteristic of the link located in the feedback is not inverse, which does not allow us to consider the system as a counter-parallel connection with negative feedback, which reduces the overall measurement error of the entire measurement complex.

The technical result is the expansion of the range of flow measurement, its separation into two parts with a decrease in the measurement level in the first part of the range, without lowering the upper value of the second part of the range, reducing the error of the measuring circuit of the first part of the range, considering the changes in the values of the medium flows as information signals between the links of the measuring system , as a counter-parallel connection with negative feedback, the possibility of obtaining different functional relationships between the values of the main and of inverse medium flows.

The technical result is achieved by the fact that in the proposed method for measuring the flow rate of the medium, the main stream is summed with the return flow, the total flow is carried out through the main flow meter, it is measured, then it is divided into two streams, one of which is considered equal to the incoming one and sent to the load, the other is considered reverse, measure with your flow meter and subtract from the total flow, characterized in that they divide the entire measurement range into two parts - the first part of the measurement with reverse flow, the second part of the measurement without reverse eye, in the first part of the return flow range forcibly fed to the main stream for adding, changing its value inversely to the magnitude of the main stream in the second part of main flow rate range is measured primary flowmeter without backflow.

In addition, according to the invention, a relationship is established, proportional and inverse, between the return flow and the main flow.

In addition, according to the invention, the return flow channel is used as a bypass when measured in the second part of the range.

In addition, according to the invention, the return flow is constant.

The drawing shows a functional diagram of a device with a reduced initial level of measurement (threshold) that implements the proposed method for measuring the flow rate of the medium.

The main stream 1 of the medium passes through the adder 2 streams, forming a total stream 3, the main flow meter 4, the separator 5 streams to output 6 to the load. In adder 2, the return stream 7 is connected to the main stream 1, which is separated from the total stream 3 in the stream splitter 5, forming a forced circulation 7 of the return flow rate through the main flow meter 4. The return flow 7, measured by its flow meter 9, is formed under the influence of a pump (for example micropump) 8, controlled through the power supply 10 by the device 11 signal comparison. From the main flow meter 4 and the flow meter 9 of the return flow, the signals are compared in the device 11 and the value of the return flow 7 is subtracted from the total flow 3 and the signal of the actual flow of the main flow 1 is fixed on the indicator 12. It is assumed that after the subtraction procedure the flow 6 that passed through the load, it is considered equal in magnitude to the main stream 1 with some error ζ. When the magnitude of the main stream 1 changes, for example, proportionally, with the opposite sign (inverse), the magnitude of the reverse flow 7 changes.

The entire measurement range is divided into two parts: in the first, the return flow 7 works, in the second, the return flow does not work, in the first part of the range, the return flow 7 is forcibly directed to the main flow 1, the value of the return flow 7 is changed:

- increase it with a decrease in the main stream 1 to a consistent (selected lower) value of the first part of the range or

- reduce its value to zero as the main stream 1 increases to a consistent (selected upper) value of the first part of the range.

In the first part of the range, the return flow 7 is subtracted from the total flow 3, fixing the value on the indicator 12, in the second - the rest - part of the measuring range at zero value of the return flow 7, the main flow 1 is measured by the main flow meter 4, the signal of which directly passes through the device 11 to the indicator 12, fixing the flow rate of the main stream 1 in the second range.

In the diagram in the drawing, the feedback link 14 is a return flowmeter 9 and a pump 8, which has an inverse “flow-pressure” characteristic with respect to the change in the flow rate of the main stream, the direct chain link 13 is the main flowmeter 4, flow divider 5.

Links 13 and 14 are included in a counter-parallel circuit to reduce the relative measurement error ζ of the circuit, which is calculated by the well-known formula (D. Braslavsky. Instruments and sensors of aircraft. M., Mechanical Engineering. 1970, p. 108)

ζ = ψ ₁ ζ ₁ + ψ ₂ · ζ ₂

ψ ₁ = 1 / Σ1 + S ₁ S ₂ ) is the influence coefficient of link 1 and ζ ₁ is its relative error,

ψ ₂ = -S ₁ S ₂ / (1 + S ₁ S ₂ ) is the influence coefficient of link 2 and ζ ₂ is its relative error,

S ₁ - the steepness of the characteristic "pressure-flow rate" of a straight chain link,

S ₂ is the slope of the pressure-flow characteristic of the feedback link.

Since ψ ₂ with such a scheme of switching on the links is always with a minus sign, the overall relative error of the measurement circuit in the first part of the measurement range is reduced in comparison with the relative error of the general circuit.

The expansion of the flow measurement range is achieved by dividing it into two parts with a decrease in the measurement level in the first part of the range. The value of the return flow 7 of the feedback link 14 allows to increase the sensitivity of the main flow meter 4 to the agreed lower measurement boundary, adding a part of the flow that is not enough to start the reliable operation of the flow meter 4. In the known method, the return flow is returned to the highway (tank, tank), in which the information the field is close to zero in magnitude of the pressure signal since the pump located after the point of summing the flows determines the value of the potential before the load. In the proposed method, the return flow is returned to the information line with a pressure in a value other than zero. In this case, the inverse pressure-flow characteristic of the feedback link is necessary to implement a counter-parallel circuit with negative feedback. Those. as the potential (pressure) and the flow rate of the measured flow at the summation point increase, the flow rate of the return flow decreases according to the “P-Q” characteristic of the feedback link.

The return flow 7 begins with a conditional zero, for example, Q ₂ = 20 l / h, the working point of the interval between the reliable operation point of the main flow meter 4 (for example, Q ₁ = 40 l / h) and a reduced agreed measurement boundary (for example, Q = 20 l / h).

If there is insufficient total flow rate through channel 3, for example, Q <20 l / h and Q ₁ = Q + Q ₂ <40 l / h passing through the main flow meter 4, indicator 12 does not show the measurement process. Those. flow rate Q <20 l / h is not measured at all.

With sufficient Q ₁ = Q + Q ₂ ≥40 l / h, the total flow rate 3 passing through the main flow meter 4 and indicator 12 shows the measurement process Q = Q ₁ -Q ₂ ≥20 l / h, then the return flow value 7 decreases by excess above 20 l / h, maintaining a value of 40 l / h, and so on. The value of Q ₂ return flow 7 decreases with an increase in the main flow 1 at the command of the comparison device 11 by the power supply 10 of the pump 8 of the return flow 7. At the same time, the flow rate Q ₁ through channel 3 is constant and equal, for example, 40 l / h This maintenance of the flow rate Q ₁ = const at the selected level is necessary for the coordinated operation of the reverse flow pump 8 with an inverse characteristic (flow rate reduction) to increase the pressure drop in the inlet pipe 1 at the summation point 2.

In another embodiment, the connection between the flow rate of O ₁ and Q ₂ can be assumed that Q ₁ = var≤60 l / h and Q ₂ = const = 20 l / h, when Q ₁ = 60 l / h is reached, feedback link 14 shuts down from work. With this work of the proposed scheme, reminiscent of the work of the prototype circuit, in which the pump operates continuously, there are two drawbacks.

The first drawback is that, according to its technical data, pump 8 should be able to overcome the level of potential in channel 1 while increasing the flow rate, for example, to 60 l / h, because with an increase in flow rate Q at inlet 1, the pressure drop at the summation point increases.

The second - the most important drawback - in such a scheme of summing the main and reverse flows instead of negative feedback (OOS), positive feedback (POS) arises, which increases the measurement error in the range from a reduced threshold (20 l / h) to the start of reliable operation of the flowmeter 4 (40 l / h).

The fundamental difference between the schemes for lowering the threshold level of sensitivity in the proposed method and in the prototype in terms of determining the measurement error consists in changing the essence of the feedback - the PIC is replaced by the OOS.

The proposed method provides the opportunity to obtain various functional relationships between the values of the main and reverse flows of the medium, for example, to reduce the time constant of the links of the forward circuit, the pump 8 is turned on with a lead.

When in the process of increasing the main stream 1 the reliable operation point of the flowmeter 4 is reached, then by this moment the value of the return stream 7 is close to zero, and a further increase in the value of the main stream 1 brings it to complete disappearance. Link 14 is turned off from the measurement operation of the main stream 1 and a smooth transition to the second part of the measurement range. The entire flow rate of the main stream 1 is measured only by the main flow meter 4. The measuring range of the second part remains the same, which does not decrease when the first part of the range is turned on. The overall measurement range has been expanded and lowered the lower level of measurement of the main flow meter 4, which was previously inaccessible before turning on the reverse flow 7, without lowering the upper value of the second part of the range. The bore is closed for circulation of the flow 7 when the pump is idle and the idle pump 8 does not let flow 7 through itself.

With the open passage section of the idle pump 8, its channel can be used as a bypass with recalculation of the transmittance of the flow through the entire circuit, increasing the overall throughput of the measuring circuit and expanding the overall measuring range. At the same time, part of the main flow passes through the flow section of the pump 8.

For small bypass cross-sections, when measured in the second part of the range, this flow can be neglected.

Claims (4)

1. The method of measuring the flow rate of the medium, in which the main stream is summed with the return flow, conduct the total flow through the main flow meter, measure it, then divide it into two flows, one of which is considered equal to the incoming one and sent to the load, the other is considered the opposite, measured they are subtracted by their flowmeter from the total flow, characterized in that they divide the entire measurement range into two parts - the first part of the measurement with reverse flow, the second part of the measurement without return flow, in the first part of the range the return flow rinuditelno fed to the main stream for adding, changing its value inversely to the magnitude of the main stream in the second part of main flow rate range is measured primary flowmeter without backflow. 2. The method of measuring the flow rate of a medium according to claim 1, wherein a connection is established between the return flow and the main proportional and inverse. 3. The method of measuring the flow rate of a medium according to claim 1, wherein the return flow channel is used as a bypass when measuring in the second part of the range. 4. The method of measuring the flow rate of the medium according to claim 1, in which the return flow has a constant value.