RU122739U1 - VALVE RETURN FREEZING - Google Patents

Abstract

1. Antifreeze check valve, containing a tubular body welded with a nozzle, in the channel of which a check valve with inlet and outlet channels is located, characterized in that a spacer is installed between the nozzle and the tubular body, inside of which the outlet channel of the check valve is passed. Antifreeze check valve according to claim 1, characterized in that the channels connecting the check valve with the tubular body are made with a confuser characteristic. The non-freezing check valve according to claim 1, characterized in that the end of the outlet channel passed through the spacer is located between the axis of the tubular body and the wall of the latter connected to the spacer.

Description

The utility model relates to mechanical engineering, namely to valve engineering, and can be used to transfer gas from the annular space of the wellhead reinforcement to the discharge line and to prevent overflow of the produced medium into the annular space of the wellhead reinforcement.

Known non-freezing wellhead check valve (see prospectus of OJSC AK “Corvette” 210AF 16.000) containing a tubular body perpendicular to the axis of which a cylindrical cup is welded;

The disadvantages of the known solutions include the placement of the glass in the cavity of the passage section of the tubular body, which almost completely blocks the passage section of the outflow line of the wellhead reinforcement, creating resistance to the flow of the producing fluid.

Also known is a non-return check valve (see RU 93480 U1 F16K 15/02) a prototype comprising a tubular body perpendicular to the axis of which a cylindrical cup is welded coaxially in the latter there is a check valve whose inlet channel is enclosed by a pipe with an axis perpendicular to the axis of the tubular body and the output channel is connected to the inner cavity of the tubular body.

The disadvantages of this technical solution also include the location of the glass in the cavity of the bore of the tubular body, which also reduces the bore of the outlet line of the wellhead fittings, creating resistance to the flow of the medium.

The technical task of this utility model is to create a non-freezing check valve with minimal flow resistance of the flow of the medium in the flow line of the wellhead valves.

The problem is solved in that the non-freezing check valve containing a tubular body welded with a glass, in the channel of which there is a check valve with inlet and outlet channels and between the glass and the tubular body there is a spacer inside which the check valve output channel is passed, and the channels connecting the check valve with a tubular body made with the characteristic of a confuser, and the end of the output channel passed through the spacer is located between the axis of the tubular body and the wall of the latter is connected CSOs are included.

Figure 1 shows a longitudinal section of a non-freezing check valve.

The non-freezing check valve contains a tubular body 1, a spacer 2, a glass 3 with a back-lock located in it, the ball of which 4 interacts with the nut 5 fixed in the glass with a nut 6. The ball lifts the stop 7 fixed in the glass with a clamp 8. A back-lock is located between the inlet channel 9 and output channel 10.

Non-freezing check valve operates as follows.

The housing 1 is mounted on the outlet line of the wellhead valve, and the inlet channel 9 is connected to the annulus of the wellhead valve.

Excess gas from the annulus enters the inlet channel 9, then through the non-return valve, raising the ball 4 to the stop 7 it enters the outlet channel 10 and into the inner cavity of the tubular body 1, i.e., into the flow line of the wellhead fitting in which the produced medium with positive temperature is constantly present .

When the gas pressure drops in the inlet channel 9, the ball 4 lowers onto the saddle 5, blocking the return flow of the produced medium into the annulus of the wellhead reinforcement.

Thus, due to the fact that in the inner cavity of the tubular casing there is an outlet channel of the return shutter with a length shorter than the radius of the inner diameter of the tubular casing, the flow area of the latter decreases slightly, practically without creating hydraulic resistance on the outflow line of the wellhead reinforcement.

Moreover, thanks to the spacer between the glasses and the tubular body, the convenience of inspection and maintenance (access to the clamp 8) of the wellhead increases, and due to the fact that starting from the input channel 9 and ending with the output channel 10 i.e. Throughout the channel passing through the check valve, the confuser characteristic is preserved, which excludes gas expansion, which is the main factor in the formation of frozen plugs.

And only at the exit from channel 10 does gas expand, i.e. in the inner cavity of the pipe, there is always a positive temperature of the medium, which ultimately guarantees the constant operation of the non-freezing check valve.

Claims (3)

1. Non-freezing check valve, comprising a tubular body welded with a glass, in the channel of which there is a check valve with inlet and outlet channels, characterized in that a spacer is installed between the glass and the tubular body, inside of which a check valve output channel is passed. 2. Non-freezing check valve according to claim 1, characterized in that the channels connecting the check valve to the tubular body are made with a confuser characteristic. 3. The non-freezing check valve according to claim 1, characterized in that the end of the outlet channel passed through the spacer is located between the axis of the tubular body and the wall of the latter connected to the spacer.