RU2707891C1 - Pulsed pressure generating device - Google Patents

Abstract

FIELD: instrument engineering.

SUBSTANCE: invention relates to instrument-making, in particular, to devices for graduation, verification and calibration of pressure sensors. Disclosed device for creation of pulsating pressure comprises housing equipped with working chamber of pulsating pressure and made with channels of supply, discharge, gas suction and blind cylindrical bore, in which a cylindrical distributor with a transverse recess on the outer surface is placed with possibility of rotation, and a connecting channel in the form of a slit-like chamfer, which serves for alternating communication of the gas supply channel with the pulsating pressure chamber and the latter with the gas discharge channel, wherein the gas suction channel in the device housing and the transverse groove on the cylindrical distributor surface are offset together respectively along the device housing and the cylindrical distributor from the gas supply and discharge channels to the same distance, excluding the communication of the transverse groove of the cylindrical distributor with the gas supply and discharge channels during its rotation, and on the surface of the blind cylindrical bore of the device housing from the gas discharge channel in the direction of the transverse groove there is a longitudinal groove connecting the gas discharge channel and the transverse groove of the cylindrical distributor during its rotation.

EFFECT: design of a device which provides a wide dynamic range of positive and (or) negative pressure pulsations in a gaseous medium.

1 cl, 22 dwg

Description

The invention relates to instrumentation, in particular to devices for calibration, calibration and calibration of pressure sensors.

A device for creating a pulsating pressure is known, comprising a housing provided with a working chamber of pulsating pressure and gas discharge and supply channels, and a distributor having rotation and equipped with a channel for alternately communicating the working chamber with gas supply and removal channels, the housing is made with a blind cylindrical bore, in which the distributor is made in the form of a cylindrical rod, and the working chamber is formed by the inner surface of the cylindrical bore of the housing and the ends of the distribution elitel and boring of the case (SU No. 838478, G01L 27/00, 1981)

The disadvantages of the device are: its inefficiency due to the lack of the possibility of pressure relief before applying to the channel of the subsequent pulses (pulsations) of pressure, if necessary, connect a calibrated and reference (reference) pressure sensor; narrow dynamic range of pulsations due to the small volume of the working chamber of the pulsating pressure in comparison with the volume of the internal cavities of the gas exhaust channel, calibrated and reference pressure sensors and fittings, providing the connection of these sensors to the gas exhaust channel; the impossibility of creating pulsations with negative pressure (creating a vacuum).

A device for creating a pulsating pressure, comprising a housing equipped with a working chamber of a pulsating pressure and channels for the removal and supply of gas, and a distributor made in the form of a cylindrical rod having rotation and equipped with a channel for lateral communication of the working chamber with the channel for supplying and removing gas, the housing is additionally equipped with a channel for suctioning gas from the gas outlet channel, which ensures the creation of negative pressures in the gas exhaust channel and a recess in the distributor connecting and rotating the channel for suctioning gas from the gas exhaust channel and the gas exhaust channel (KZ No. 21238, G01L 27/00, 2009)

The disadvantage of the device are: the inability of the device to create a pulsating pressure, due to its design feature - the channels of supply, exhaust, gas suction and undercut are made in one plane; narrow dynamic range of pulsations due to the small volume of the working chamber of the pulsating pressure in comparison with the total volume of the internal cavities of the gas exhaust channel, calibrated and reference pressure sensors and fittings, providing the connection of these sensors to the gas exhaust channel.

The technical result of the invention is a device that provides a wide dynamic range of pulsations of positive and (or) negative pressure in a gas environment.

The required technical result is achieved in that in a device for creating a pulsating pressure, comprising a housing equipped with a working chamber of a pulsating pressure and made with channels for supplying, discharging, suctioning gas and a blind cylindrical bore, into which a cylindrical distributor having an external surface is placed with rotation transverse groove, and at the end - a connecting channel in the form of a slit-like bevel, which serves, during rotation of the distributor, for alternately communicating the gas supply channel from the chambers of the pulsating pressure and the latter with a gas exhaust channel, the gas suction channel in the device body and the transverse groove on the surface of the cylindrical distributor are offset together respectively along the device body and the cylindrical distributor from the gas supply and exhaust channels by the same distance, excluding the message of the transverse groove of the cylindrical distributor with channels for supplying and removing gas during its rotation, and on the surface of a blind cylindrical bore of the device body from the channel and the gas in a direction transverse longitudinal undercut groove is formed connecting the gas discharge duct and a transverse cylindrical recess of the distributor when it rotates.

In addition, the creation of a wide dynamic range of pulsations of positive and (or) negative pressure in the gas medium can be achieved by the fact that the working chamber of the pulsating pressure is formed by a blind bore of the end of the cylindrical distributor and the surface of the blind cylindrical bore of the housing adjacent to the end of the distributor, and the connecting channel is made in the wall of the working chamber at the level of the gas supply and exhaust channels.

In FIG. 1 - FIG. 3 shows, respectively, longitudinal and transverse sections of a device for generating a pulsating pressure, when the distributor is in the position of supplying high pressure gas to the working chamber of the pulsating pressure and exhaust or exhaust gas from the gas outlet channel; in FIG. 4 - FIG. 11 shows transverse sections of the device (Fig. 1) when the distributor is sequentially in different positions 0 °, 90 °, 270 °, 360 ° (0 °) within one revolution when rotating clockwise in the device body; in FIG. 12 - FIG. 14 shows, respectively, longitudinal and transverse sections of a device with a pulsating pressure working chamber formed by a bore of the distributor end and a housing bore surface adjacent to the end of the distributor when the distributor is in the position of supplying high pressure gas to the working chamber and discharging or exhausting gas from the gas outlet channel ; in FIG. 15 - FIG. 22 shows transverse sections of the device (FIG. 12) when the distributor is sequentially in different positions 0 °, 90 °, 270 °, 360 ° (0 °) within one revolution when rotating in the clockwise direction in the device case

A device for creating a pulsating pressure comprises a housing 1 provided with a working chamber of a pulsating pressure 2, and also made with a blind cylindrical bore 3 and gas supply channels 4, exhaust 5 and gas suction 6.

A rotary cylindrical distributor 7 is installed in the blind cylindrical bore 3, having an end connection channel 8 in the form of a slant-like bevel, which serves, during rotation of the distributor 7, for alternately communicating the gas supply channel 4 with a pulsating pressure chamber 2 and a chamber 2 with a gas removal channel 5.

On the outer surface of the cylindrical distributor 7, a transverse undercut 9 is made.

The gas suction channel 6 in the housing 1 and the transverse groove 9 on the surface of the cylindrical distributor 7 are offset respectively along the housing 1 and the cylindrical distributor 7 from the supply channels 4 and the gas outlet 5 by the same distance 10, sufficient to exclude communication, when the cylindrical distributor 7 is rotated, transverse grooves 9 with a supply channel 4 and a gas exhaust channel 5.

On the surface of the cylindrical bore 3 from the channel 5 in the direction of the transverse groove 9, a longitudinal groove 11 is made long enough to communicate the gas exhaust channel 5 with the transverse groove 9 during rotation of the cylindrical distributor 7.

The working chamber of the pulsating pressure 2 can be formed by a blind bore 12 of the end face of the cylindrical distributor 7 and the surface 13 of the blind cylindrical bore 3 of the housing 1 adjacent to the end of the cylindrical distributor 7, and the connecting channel 8, in this case, must be made in the wall 14 of the working chamber 2 at the level of supply channels 4 and gas outlet 5.

A device for creating a pulsating pressure (Fig. 1) works as follows.

To generate high pressure pulses, a high pressure source is connected to the gas supply channel 4, a calibrated pressure sensor and a standard (reference) pressure sensor (not shown in the figures) are connected to the gas exhaust channel 5, the gas suction channel 6 is left free.

In the initial position of the distributor 0 ° (Fig. 2 and Fig. 3, the same Fig. 4 and Fig. 5) through the gas supply channel 4 and the connecting channel 8 into the working chamber of the pulsating pressure 2 high pressure gas is supplied from the gas exhaust channel 5 through the longitudinal groove 11 and the transverse groove 9, gas is discharged into the gas suction channel 6.

When the cylindrical distributor 7 is rotated clockwise 90 ° (Fig. 6 and Fig. 7), the gas supply channel 4, the gas exhaust channel 5 and the longitudinal recess 11 are blocked by the surface of the housing of the cylindrical distributor 7, the connecting channel 8 is blocked by the surface of the blind cylindrical bore 3, the connecting channel 6 and the transverse groove 9 are isolated from other channels, in the working chamber of the pulsating pressure 2 there is a gas under high pressure and has the parameters: P _K is the pressure, V _K is the total volume of the chamber 2 and channel 8, T _K is the temperature.

When the cylindrical distributor 7 is rotated clockwise 180 ° (Fig. 8 and Fig. 9), the gas supply channel 4, the gas suction channel 6, the transverse groove 9 and the longitudinal groove 11 are blocked by the housing surface of the cylindrical distributor 7, the connecting channel 8 communicates with the channel gas outlet 5 and high-pressure gas from the pulsating pressure chamber 2 flows into the gas outlet channel 5. Thus, in the gas outlet channel 5, a front of a high-pressure gas pulse is created.

When the cylindrical distributor 7 is turned clockwise by 270 ° (Fig. 10 and Fig. 11), the gas inlet 4 and gas suction channels 6 are blocked by the housing surface of the cylindrical distributor 7, the gas exhaust channel 5, the grooves transverse 9 and longitudinal 11 communicate and are blocked by the housing surface a cylindrical distributor 7, the connecting channel 8 is blocked by the surface of the cylindrical bore 3. In the suction channel of the gas 5, high pressure is maintained. The gas in channel 5 has the parameters: P ₅ is the pressure, V ₅ is the total volume of the internal cavities of the gas exhaust channel 5, the calibrated pressure sensor and connecting fittings, and T ₅ is the temperature.

If the temperatures T _K and T _{5 are} equal, the pressure value P ₅ according to the Boyle-Mariot law is determined by the expression

From the expression (1) it follows that the larger the volume of the chamber of the pulsating pressure 2, the wider the dynamic range of pulsations can provide a device for creating a pulsating pressure.

When the cylindrical distributor 7 is rotated clockwise 360 °, which corresponds to the initial position 0 ° (Fig. 4 and Fig. 5), high pressure gas is supplied through the gas supply channel 4 and the connecting channel 8 to the pulsating pressure chamber 2 from the exhaust channel gas 5 through the recesses of the longitudinal 11 and transverse 9, gas is discharged into the gas suction channel 6, thereby creating a recession (slice) of the high-pressure gas pulse in the gas exhaust channel 5.

Thus, in one revolution of the cylindrical distributor 7, the device (Fig. 1) generates one pulse of high gas pressure.

The high pressure gas pulses generated by the device (Fig. 1) have the following parameters: amplitude, the value of which is equal to P ₄ according to expression (1); duration, the value of which is equal to half the duration of one revolution of the distributor 7; the follow-up period, the value of which is equal to the duration of one revolution of the distributor 7.

To form negative (lower than atmospheric) pressure pulses, a high pressure gas source is connected to the gas supply channel 4, a calibrated pressure sensor and a standard (reference) pressure sensor are connected to the gas exhaust channel 5, and a gas suction device is connected to the gas suction channel 6.

At the 0 ° position (Fig. 4 and Fig. 5) of the cylindrical distributor 7 from the gas exhaust channel 5, the longitudinal 11 and transverse 9 are sucked into the channel 6 through the recesses 9, thereby forming a front of negative pressure pulses.

From the gas supply channel 4, through the connecting channel 8, a high pressure gas enters the pulsating pressure chamber 2, the value of which is selected based on expression (1) so that in the intervals between the negative pressure pulses the pressure in the gas exhaust channel 5 corresponds to atmospheric .

At a 180 ° position (Fig. 8 and Fig. 9) of a cylindrical distributor 7, a high-pressure gas enters from the pulsating pressure chamber 2 through the connecting channel 8 into the gas exhaust channel 5, thereby decreasing (cutting) negative pressure pulses.

Thus, in one revolution of the cylindrical distributor 7, the device (Fig. 1) generates one pulse of negative gas pressure.

The amplitude of the pulses of the negative gas pressure is determined by the power of the gas suction device, which during the communication of the exhaust channels 5 and the gas suction 6 must suck the gas from the channel 5 to the desired negative pressure value.

The pulse duration of the negative gas pressure is equal to half the duration of one revolution of the cylindrical distributor 7. The pulse repetition period of the negative gas pressure is equal to the duration of one revolution of the distributor 7.

To form a sequence of pulses of positive (above atmospheric) and negative (below atmospheric) pressure, a high pressure source is connected to gas supply channel 4, a calibrated pressure sensor and a standard (reference) pressure sensor are connected to gas exhaust channel 5, a device is connected to gas suction channel 6 gas suction.

At the 0 ° position (Fig. 4 and Fig. 5) of the cylindrical distributor 7 from the gas suction channel 5, the longitudinal 11 and transverse 9 are sucked into the channel 6 through the recesses 9, thereby decreasing (cutting) the high pressure pulses and the front of the negative pressure pulses. From the gas supply channel 4, through the connecting channel 8, high pressure gas enters the chamber 2.

At a 180 ° position (Fig. 8 and Fig. 9) of a cylindrical distributor 7, a high-pressure gas enters a gas outlet 5 from a pulsating pressure chamber 2 through a connecting channel 8, thereby decreasing (cutting off) the negative pressure pulses and the front of the high pressure pulses .

Thus, in one revolution of the distributor 7, the device (Fig. 1) generates one pulse of negative gas pressure and one pulse of high pressure.

The operation of the device for creating a pulsating pressure, the design of which is shown in FIG. 12 is similar to the operation of the device, the construction of which is shown in FIG. one.

Using the proposed device will ensure the creation of a wide dynamic range of pulsations of positive and (or) negative pressure in the gas medium during calibration, calibration and calibration of pressure sensors.

Claims (2)

1. A device for creating a pulsating pressure, comprising a housing equipped with a working chamber of a pulsating pressure and made with channels for supplying, discharging, suctioning gas and a blind cylindrical bore, into which a cylindrical distributor having a transverse groove on the outer surface, and at the end - a connecting channel in the form of a slit-like bevel, which serves for alternating communication of the gas supply channel with a pulsating pressure chamber and the latter with a gas exhaust channel, characterized in that the gas suction anal- on the surface of a blind cylindrical bore of the device body from the gas exhaust channel in the direction of the transverse groove, a longitudinal recess connecting the gas exhaust channel and the transverse recess of the cylindrical distributor during its rotation. 2. A device for creating a pulsating pressure according to claim 1, characterized in that the working chamber of the pulsating pressure is formed by a blind bore of the end face of the cylindrical distributor and the surface of the blind cylindrical bore of the housing adjacent to the end of the cylindrical distributor, and the connecting channel is made in the wall of the working chamber of the pulsating pressure level of gas supply and exhaust channels.

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