RU2340876C1 - Jet flow sensor - Google Patents

Abstract

FIELD: physics; measurements.

SUBSTANCE: proposed jet flow sensor has an orifice with stream lined body, between which and the case of the sensor, a channel is formed, which has a neck. The sensor also has frequency jet converter with fluidic switches, joined in succession depending on the negative feedback type. An output air-to-electric signal switch is connected to one of the fluidic switches. The inlet nozzles of the switches are joined to the input of the sensor through the feed channel and the input of the orifice. The drain cavities of the switches are joined to the neck of the orifice, while the output of the orifice is joined to the output of the sensor. The frequency jet converter is put into the stream lined body, in which there is an inlet opening of the feed channel, which is in form of slits or a slit, which joins the drainage channels of the switches to the neck.

EFFECT: increased accuracy of measuring flow rate in a wide temperature range.

7 cl, 1 dwg

Description

The invention relates to techniques for measuring flow, in particular to means for measuring the flow of gases or liquids.

Known jet flow sensor containing jet switches, the power nozzles of which are connected to the inlet, and the drainage cavity with the outlet of the flow sensor. The output nozzles of each switch are connected to the control nozzles of the subsequent switch by communication channels. A pneumatic electroconverter is connected to the output nozzles of one of the switches [see A.S. USSR No. 857714, class G01F 1/48, 1977].

When measuring large flows, this device has a large weight and dimensions due to the large dimensions of the jet switches, as well as an insufficiently wide range of flow measurements with a linear characteristic, which prevents its widespread use.

Known inkjet flow sensor containing a primary inkjet frequency flow sensor (PSCHDR) and a constricting device (CS) connected in parallel PSCHDR [see "Devices and devices of inkjet technology." Leningrad, LDNTP, 1980, p.26].

This device has a large error in measuring flow rates that vary over a wide range, since at low flow rates the differential on the PSHDR is not proportional to the square of the flow (as on a standard control system) due to the significant influence of the viscosity forces on the velocity profile in the nozzle of the power supply of the jet switch, due to which the flow rate of the SU and the power nozzle of the PSCHDR jet switch when the flow rate varies over a wide range vary in different ways, which leads to the formation of a large error in the sensor operation.

The closest in technical essence to the claimed device is an inkjet flow sensor containing a control system with a streamlined body and a primary inkjet converter having inkjet switches connected in series, the outputs of the switches being connected in the form of negative feedback, and the output pneumatic electroconverter connected to the output channels of one of the switches, the nozzle of the power supply of the switches through the supply channel and the input of the control system are connected to the sensor input, the drainage cavity of the switch connected to the throat SU, the output of which is connected to the output of the sensor (see. Russian Patent №2253844 of 13.09.04, IPC ⁷ G01F 1/20).

This device has a large error in measuring gas flow rates over a wide range of ambient temperatures. For example, in winter, when installing the sensor in a heated room, the air temperature in which can be on the order of + 30 ° C, the temperature of the outdoor air and gas, the flow rate of which is measured, can be on the order of minus 40 ° C. Since the main flow of cold gas is carried out through the flow part of the control system, and the converter with the minimum flow rate is located outside the flow part, conditions are created for heat exchange of gas in the channels of the switches with warm room air. Therefore, the modes of gas flow through the throat of the SU and through the nozzles of the switches are significantly different. When the flow rate changes, the temperature separation also changes, which affects the accuracy of determining the flow rate and volume of gas consumed. Additionally, it can be noted that the known device has a large mass and dimensions due to the separate execution of the control system and the primary inkjet converter.

The technical result to which the claimed invention is directed is to create a flow meter having high accuracy, low weight and dimensions, operable in a wide range of flow rate and temperature (ambient air and gas, the flow rate of which is measured).

To achieve the technical result, the jet flow sensor comprises a housing, a constricting device with a streamlined body, between which a channel is formed with a throat, a frequency jet converter with jet switches connected in series as a negative feedback, and an output pneumatic electro-signal converter connected to the output the channels of one of the switches, and the nozzles of the power supply of the switches through the inlet of the supply channel are connected to the sensor input, azhnye switches cavity - a neck orifice, and the exit orifice is connected to the sensor output, wherein the frequency converter is installed in a jet flow body defining a supply channel inlet and a slit connecting the drains of switches with a throat.

The outer surface of the streamlined body can be made in the form of a surface of revolution.

The throat may have a width equal to 1.2 ± 0.6 of the hydraulic diameter of the nozzles supplying the jet switches.

The width of the slit in the streamlined body can be equal to 0.7 ± 0.3 of the hydraulic diameter of the nozzles supplying jet switches.

The width of the channel in front of the slit can be made by 0.1 ± 0.05 of the hydraulic diameter of the nozzles supplying jet switches less than the width behind the slit.

The inlet of the channel for supplying air to the jet switches can be made in a streamlined body in a place where the width of the channel between the body and the streamlined body is not less than 4 times the width of the throat.

The inlet of the feed channel can be made in the form of slots (slots).

A distinctive feature of the claimed invention, namely the installation of a frequency jet converter in a streamlined body, in which the inlet of the feed channel and the slot connecting the drainage channels of the switches with the throat are made, reduces the weight and dimensions of the sensor due to the use of space in the streamlined body), increase its static and dynamic accuracy (by eliminating the influence of ambient temperature on the jet converter and faster heating (cooling) of the jet converter (in btekaemom body) with increasing (decreasing) the temperature of the medium).

The execution of the outer surface of the streamlined body in the form of a surface of revolution simplifies the design, makes the sensor more technological, and reduces the cost of the sensor.

The execution of the throat of the channel between the housing and the streamlined body with a width equal to 1.2 ± 0.6 of the hydraulic diameter of the nozzles for power supply of the jet switches allows to increase the accuracy of the sensor by ensuring the same mode of flow of the measured medium through the channel and through the nozzles of the switches.

The execution in the streamlined body of the gap connecting the drainage channels of the switches with the throat with a width of 0.7 ± 0.3 of the hydraulic diameter of the power nozzles of the jet switches allows to obtain increased accuracy of the sensor.

The execution between the housing of the sensor and the streamlined body of the channel, the width of which in front of the slit can be made by 0.1 ± 0.05 of the hydraulic diameter of the nozzles for power supply of the jet switches less than the width behind the slit, allows to obtain increased accuracy of the sensor.

The inlet of the channel for supplying air to the jet switches in the streamlined body in a place where the channel width between the body and the streamlined body is not less than 4 times the throat width allows you to get the differential necessary for their operation on the jet switches in a wide range of flow rates (increases the differential pressure on the switches), which extends the operating range of the sensor.

The implementation of the inlet of the supply channel in the form of slots (slots) simplifies the design of the sensor, reduces its weight, dimensions and cost.

The scheme of the jet flow sensor is shown in the drawing and described below.

An inkjet flow sensor comprises a constriction device connected to the sensor input 1 with a streamlined body 2, which can be made in the form of a surface of revolution, inside which a frequency jet converter 3 is installed. The converter 3 has jet switches 4 connected in series according to the type of negative feedback and, for example through the matching switch 5 with the input channels of the pneumatic transducer 6, the outputs of which are hermetically removed through the streamlined body 2 and the housing 7 outside the flow part Occupancy. The power nozzles of the jet switches 4 and 5 are connected through the cavity 8 and the inlet of the supply channel, for example, in the form of slots (slots) 9 in the streamlined body 2 with the input 1, and the drain channels of the jet switches are connected through the drain cavity 10, for example, through the end slot 11 in a streamlined body 2 (and the slot width can be equal to 0.7 ± 0.3 of the hydraulic diameter of the nozzles for power supply of the jet switches) with the neck 12 of the flow part of the narrowing device formed in the form of a channel (cross section with a minimum area, the width of which can be equal to 1.2 ± 0.6 of the hydraulic diameter of the nozzles for power supply of the jet switches) between the housing 7 and the streamlined body 2. The width of the throat 12 in front of the slot can be made smaller than the width of the channel behind the slot by 0.1 ± 0.05 of the hydraulic diameter of the nozzles of power for the jet switches 4 The sensor input 1 through the flow part of the constriction device is connected to the output 13. The air inlet to the sensor jet switches is made in the streamlined body in a place where, for example, the channel width between the body and the streamlined body is at least 4 times the width of the mountains la 12.

Inkjet flow sensor operates as follows.

The working medium entering the input 1 of the jet flow sensor, passing through the throat 12 between the inner surface of the housing 7 and the outer profiled surface of the streamlined body 2 to the outlet 13, ejects the medium through the slot 11 from the drainage cavity 10 of the jet switches 4 and 5. At the same time, the working medium enters from the entrance 1 through the slot 9 to the power nozzles of the jet switches 4 and 5 and further into their drainage cavity 10, and then, for example, through the slot 11 into the flow part of the constricting device.

Since the jet switches 4 are connected according to the type of negative feedback, there is a periodic switching of the direction of flow of the power jet flowing out from the nozzles of the power supply of the jet switches 4. The resulting pressure (flow) pulses are fixed by a pneumatic electroconverter 6 connected directly to the output channels of one of the jet switches 4 directly or through a matching switch 5. The outputs of the pneumatic transducer 6 are hermetically removed through the streamlined body 2 and the housing 7 outside the flowing hour and a sensor. In this case, the frequency of pressure pulses (flow rate) is proportional to the flow rate of the medium being measured.

The installation of a frequency jet converter in a streamlined body, in which the inlet of the feed channel and the slot connecting the drainage channels of the switches to the throat are made, can reduce the influence of ambient air temperature on the operation of the sensor. For example, when installing the sensor in a heated room, in which in winter the air temperature can be about + 30 ° C, and the temperature of the outdoor air and gas, the flow rate of which is measured, can be about minus 40 ° C. Cold gas will pass through the flow part of the SU and through the converter located inside the flow part. The temperature of the fairing body 2, in which the converter is located, will also be minus 40 ° С. As a result of this, the converter will not have conditions for heat exchange of gas in the channels of switches with warm room air. Therefore, if there is a big difference in the temperatures of the outside air and the air in the room, there will be no temperature stratification of the sensor characteristics (unlike the known sensor, in which the converter is located outside the flow part).

The implementation of the outer surface of the streamlined body 2 in the form of a rotation surface makes the sensor more technologically advanced in manufacture.

The execution of the throat 12 with a width of 1.2 ± 0.6 of the hydraulic diameter of the nozzles for power supply of the jet switches increases the linearity of the sensor characteristics due to the similarity of the gas flow regimes in the throat 12 and in the power nozzles of the jet switches.

The implementation of the slit 11 with a width of 0.7 ± 0.3 of the hydraulic diameter of the nozzles of the power supply of the jet switches and the channel in front of the slit 11 of 0.1 ± 0.05 of the hydraulic diameter of the nozzles of the power of the switches smaller than the width behind the slit increases the linearity of the sensor characteristic (accuracy).

Additionally, it can be noted that the claimed device has a lower mass and dimensions due to the installation of the primary inkjet converter in the control system.

Claims (7)

1. An inkjet flow sensor comprising a housing, a constricting device with a streamlined body, between which a channel is formed having a throat, a frequency jet converter with jet switches connected in series as negative feedback, and an output pneumatic electro-signal transducer connected to the output channels of one of the switches, and the nozzles of the power supply of the switches through the inlet of the supply channel are connected to the input of the sensor, the drainage cavities of the switches - narrowing with the throat th device and the output orifice is connected to the sensor output, wherein the frequency converter is installed in a jet flow body defining a supply channel inlet and a slit connecting the drains of switches with a throat. 2. The inkjet flow sensor according to claim 1, in which the outer surface of the streamlined body is made in the form of a surface of revolution. 3. The inkjet flow sensor according to claim 1, in which the throat has a width equal to 1.2 ± 0.6 of the hydraulic diameter of the power nozzles of the jet switches. 4. The inkjet flow sensor according to claim 1, wherein the width of the slit in the streamlined body is 0.7 ± 0.3 of the hydraulic diameter of the nozzles for powering the jet switches. 5. The inkjet flow sensor according to claim 1, wherein the channel width in front of the slit is 0.1 ± 0.05 of the hydraulic diameter of the power nozzles of the jet switches less than the width behind the slit. 6. The inkjet flow sensor according to claim 1, in which the inlet of the channel for supplying air to the jet switches is made in a streamlined body in a place where the width of the channel between the body and the streamlined body is not less than 4 times the width of the throat. 7. The inkjet flow sensor according to claim 1, in which the inlet of the inlet channel is made in the form of slots (slots).