RU2662508C1 - Gauge - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: invention relates to the field of measurement technology and can be used to measure the pressure of gaseous and liquid substances in production and other processes. Device includes a housing with a sensor element constituting a tubular spring connected by a linkage with a transmission mechanism and a holder, with a threaded bushing in the lead-in channel of the holder to form a gap between the thread of the bushing and the thread on the wall of the supply channel.

EFFECT: elimination of pulsation releases of the pressure of the medium to be measured before it enters the internal cavity of the sensitive element of the device.

9 cl, 6 dwg

Description

The invention relates to the field of measuring equipment and can be used to measure the pressure of gaseous and liquid substances in industrial and other processes.

The following solutions are known in the art.

A known pressure gauge is shown for measuring the pressure of liquid and gaseous media, the design of which includes a housing with a sensing element in the form of a tubular spring, a transmission mechanism and a holder for a tubular spring (Mulev Yu.V. Manometers. M .: MEI, 2003, p. 53).

A disadvantage of the known device is manifested in the low mechanical reliability of its operation under pulsating loads of the measured medium.

A pressure gauge is also known that shows a set of washers with staggered holes and spacing bushings between them in the internal cavity of the holder at the entrance to the pressure gauge (RF patent No. 163269, 07/10/2016).

The disadvantage of this solution is the low efficiency of its work, especially on incompressible media.

The closest analogue of the patented solution is a pressure gauge showing a damper device in which the medium to be measured passes through a thin capillary channel formed by the wall of the internal cavity of the housing and the cone inserted into the internal cavity of the housing (Mulev Yu.V. Manometers. M .: MPEI, 2003, p. 230).

The disadvantage of the closest analogue is the technological complexity of manufacturing such a damper device, as well as the lack of efficiency of its work.

The technical problem solved by the invention is the need to eliminate the pulsating pressure surges of the measured medium before it enters the internal cavity of the sensing element of the device.

The problem is solved in that a threaded sleeve is mounted in the inlet channel of the pressure gauge.

The technical result of the invention is the elimination of pulsating pressure surges of the measured medium before it enters the internal cavity of the sensing element of the device.

The specified technical result is achieved due to the design of the pressure gauge, comprising a housing with a sensing element, connected by a rod with a transmission mechanism and a holder, while a threaded sleeve is installed in the inlet channel of the holder, with the formation of a gap between the thread of the sleeve and the thread on the wall of the inlet channel, while the sleeve has a T-shaped channel.

The sleeve is made with a protrusion that prevents its free movement.

The sleeve on the free side has a nipple that defines the installation of the gasket.

The gasket is designed to seal the pressure gauge holder in the landing socket of the object where measurements are made. In the absence of a gasket, the medium may enter the bushing thread through the gap between the protrusion and the holder body. To avoid this, a T-shaped channel is made inside the sleeve from the side of the central hole of the holder, through which the medium enters the gap between the threads.

The specified technical result is achieved due to the fact that passing the path through the T-shaped channel and the gap between the threads of the sleeve and the channel of the holder, the medium cannot quickly transmit a pressure impulse through a very small gap between the thread of the sleeve and the thread of the holder body, the pulse "brakes" and the sensing element is not exposed to sudden surges in the measured pressure.

A cylinder is installed in the internal cavity of the pressure gauge holder, through which an additional tube passes, leading the medium to the sensitive element of the device.

The inlet tube and cylinder form a dead end space in which air is in operation. The presence of air in this volume provides cushioning (damping, smoothing) of pressure surges of an incompressible fluid.

Next, the solution is illustrated by reference to the figures, which show the following.

FIG. 1 - Installation diagram of a screw insert in the inlet channel of the pressure gauge holder.

FIG. 2 - Side view of the screw insert.

FIG. 3 - Top view of a screw insert.

FIG. 4 - Installation diagram of an additional supply tube in the pressure gauge holder.

FIG. 5 - An embodiment of the circuit of FIG. 4 as a remote unit.

FIG. 6 - An embodiment of the circuit of FIG. 4 with an enlarged feed channel.

The manometer showing includes a housing with a sensing element 9 connected by a rod to the transmission mechanism and holder 1. A threaded sleeve 2 is installed in the inlet channel 11 of the holder 1, with a gap between the thread 3 of the sleeve 2 and the thread on the wall of the inlet channel 11 (the gap is not shown in the drawings ) The sleeve from the side of the inlet of the holder has a channel 4, coaxial to the channel of the holder and communicating with it channel 6, transverse to the channel of the holder with the formation of a T-shaped channel.

The difference between the threaded tolerances of the internal and external threads of the sleeve and the inlet channel is proportional to the damping and viscosity of the damped medium, determined experimentally.

The sleeve is made with a protrusion 5, preventing its free movement.

The sleeve on the free side has a nipple 13, which determines the installation of the gasket 7 for sealing the pressure gauge holder in the seat of the object where measurements are made.

A cylinder 8 is installed in the internal cavity of the pressure gauge holder, through which an additional tube 10 passes, leading the measured medium to the sensing element 9 of the device. The supply tube 10 at the inlet of the measured medium is rotated 10 ÷ 180 ° relative to the direction of movement of this medium.

The specified cylinder can be placed in a separate remote unit (Fig. 5), as well as with an enlarged supply channel (Fig. 6). In both cases, a constricting device 12 is installed at the entrance to the supply channel.

The transmission mechanism is a tribo-sector mechanism, on the driven axis of which there is a showing arrow with a return coil spring and a dial.

The holder body and the shell of the pressure gauge are interconnected by means of a threaded connection with a nominal diameter of 50, 63, 100, 160 mm and a thread pitch of H5 mm.

The device operates as follows.

The liquid enters the central hole of the holder body, from where it enters the supply T-shaped channel of the holder, then into the gap between the thread 3 of the screw 2 and the thread of the channel 11 of the holder 1, after which it enters the supply pipe 10 through the constricting device 12.

Entering the internal cavity of the sensing element 9 and acting on this element, the medium transmits the measured pressure, i.e. there is a change in the geometry of the sensor under the influence of pressure.

The linear movement of the elastic sensor element is converted into a circular motion of the indicating arrow through a transmission mechanism connected via a rod to the sensor element.

Claims (9)

1. A manometer showing, comprising a housing with a sensing element, which is an elastic element connected by a rod or pusher with a transmission mechanism and a holder, characterized in that a threaded sleeve is installed in the supply channel of the holder with a gap between the thread of the sleeve and the thread on the wall of the supply channel, while the sleeve has a T-shaped channel. 2. A pressure gauge according to claim 1, characterized in that the sleeve is made with a protrusion. 3. A pressure gauge according to claim 1, characterized in that the sleeve on the free side has a nipple that defines the installation of the gasket. 4. A pressure gauge according to claim 1, characterized in that the internal cavity of the pressure gauge holder includes a cylindrical volume through which the tube leading to the sensing element passes. 5. A pressure gauge according to claim 4, characterized in that a constriction device is installed at the entrance to the supply channel. 6. A pressure gauge according to claim 4, characterized in that the cylindrical volume with the tube supplying the medium to be measured is placed in a separate unit installed on the inlet to the pressure gauge of the medium to be measured. 7. A pressure gauge according to claim 6, characterized by the installation of a constricting element at the entrance to the inlet tubular channel. 8. A pressure gauge according to claim 5, characterized in that the inlet pipe channel at the inlet of the measured medium is rotated 10 ÷ 180 ° relative to the direction of movement of this medium. 9. A pressure gauge according to claim 1, characterized in that the housing and the sheath are interconnected by means of a threaded connection with a nominal diameter of 50, 63, 100, 160 mm and a thread pitch of 1 ÷ 5 mm.

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