CN204900969U - Formula of relying on oneself segmentation pressure control valve - Google Patents

Abstract

The utility model discloses a self-operated sectional pressure control valve, which comprises a valve body. A sliding chamber is arranged in the valve body, a fluid outlet is arranged on the side wall of one end of the sliding chamber, and a fluid outlet is arranged on the side wall of the other end of the sliding chamber. Inlet, the sliding chamber is provided with a valve core, the middle of the valve core is provided with a circumferential annular groove, one end of the sliding chamber is provided with a pressure chamber, and the other end is provided with a valve seat, one end of the valve core is offset against the valve seat by a spring, and the pressure chamber passes through The liquid inlet hole communicates with the fluid inlet. The utility model has a simple structure. By controlling the pressure at the inlet and outlet of the valve, the valve can be automatically opened within a certain pressure range. When the pressure is lower or higher than the range, the valve is in a closed state. The opening and closing of the valve can be controlled by the pipeline pressure without external driving force, so as to achieve further control of the pipeline.

Description

A self-operated sectional pressure control valve

technical field

The utility model relates to a valve device, in particular to a self-operated segmental pressure control valve. It is suitable for the occasions where fluid pressure is used to automatically control the pipeline system, especially for extreme occasions (such as underground formations) where third-party actuators (such as solenoid valves and pneumatic valves) cannot be used.

Background technique

In the process of fluid testing and control, it is often necessary to control the fluid branch according to the pressure. There are mature products such as self-operated pressure reducing valves, solenoid valves, pilot safety valves, etc. However, third-party actuators that require pneumatic or electromagnetic signals cannot be well adapted to the harsh environment of deep drilling and ultra-remote control.

Products that rely on the pressure difference of the medium to drive the disc or the valve core to move back and forth to realize the control of the system flow and pressure have also been reported, such as the "self-operated regulating valve" published by the utility model patent CN102313055A. Both ends require a throttle valve to cooperate. In addition, similar technologies represented by this scheme cannot realize self-operated sectional pressure control, that is, self-operated control valves with both starting pressure and closing pressure.

Utility model content

The purpose of this utility model is to overcome the shortcomings and deficiencies of the previous drilling imaging technology, and provide a self-operated sectional pressure control valve, which can automatically open within a certain range of pressure. When the valve inlet pressure reaches a certain value , the valve opens, and if the inlet pressure continues to increase and is higher than a certain value, the valve automatically closes. If this type of valves with different opening pressure sections are installed in the same pipeline system, the function of controlling the automatic opening and closing of different valves can be achieved by controlling the pipeline pressure.

In order to achieve the above object, the utility model adopts the following technical measures:

A self-operated sectional pressure control valve, comprising a valve body, the valve body is provided with a sliding chamber, the side wall at one end of the sliding chamber is provided with a fluid outlet, and the side wall at the other end of the sliding chamber is provided with a fluid inlet, inside the sliding chamber A valve core is provided, and the middle part of the valve core is provided with a circumferential annular groove. One end of the sliding chamber is provided with a pressure chamber, and the other end is provided with a valve seat. One end of the valve core is offset against the valve seat by a spring. Import connectivity.

The above-mentioned valve seat part includes a valve sleeve arranged at the end of the sliding chamber. A spring seat is arranged inside the valve sleeve. One end of the spring seat passes through the valve sleeve, and the other end is provided with a bottom groove for clamping the spring. The valve core and the spring The opposite end is provided with a bottom groove for clamping the spring.

As mentioned above, a snap ring is provided on the valve sleeve.

The diameter of the pressure chamber as mentioned above is smaller than the diameter of the spool.

Compared with the prior art, the utility model has the following beneficial effects:

The structure is simple. By controlling the pressure at the inlet and outlet of the valve, the valve can be automatically opened within a certain pressure range. When the pressure is lower or higher than the range, the valve is in a closed state. The opening and closing of the valve can be controlled by the pipeline pressure without external driving force, so as to achieve further control of the pipeline.

Description of drawings

Fig. 1 is a structural diagram of the utility model, the valve body is pushed to one end of the sliding chamber by a spring, and the upper side wall of the valve body seals the fluid outlet;

Fig. 2 is a state diagram in which the valve body is in the middle of the sliding chamber, and the fluid inlet communicates with the fluid outlet through a circumferential annular groove;

Figure 3 shows that the valve body is pushed to the other end of the sliding chamber under the action of pressure in the pressure chamber, and the lower side wall of the valve body seals the fluid inlet.

In the figure: P1-fluid inlet, P2-fluid outlet, A-circumferential annular groove, B-inlet hole, C-pressure chamber, D-sliding chamber, 1-spool, 2-valve body, 3-spring, 4-valve sleeve, 5-spring seat, 6-circlip.

Detailed ways

Below in conjunction with accompanying drawing the utility model is described in further detail:

As shown in FIG. 1 , the valve core 1 is installed in the valve body 2 and forms a sliding fit with the valve body 2 . A certain space is left between one end of the valve core 1 and the valve body 2 to form a pressure chamber C, and the other end of the valve core 1 is provided with a bottom groove. The valve sleeve 4 is connected with the valve body 2 to form a cavity with a built-in spring. One end of the spring 3 is pushed against the bottom groove of the valve core 1, and the other end of the spring is pushed against the bottom groove of the spring seat 5. The big end of spring seat 5 is placed in valve sleeve 4, and the small end of spring seat 5 is compressed by valve sleeve 4, and passes valve sleeve 4. The spring 3 presses the valve core 1 against the pressure chamber C of the valve body 2 . The valve body 2 is provided with a fluid inlet P1 and a fluid outlet P2, and a liquid inlet B is opened at the fluid inlet P1, through which the fluid at the fluid inlet is introduced into the pressure chamber C.

When the pressure fluid enters the pressure chamber C, it forms an upward thrust on the end surface of the valve core 1. When the fluid inlet pressure continues to increase, the pressure of the fluid on the lower end surface of the valve core 1 also increases continuously. When the thrust increases to greater than When the downward pressure of the spring 3, the spool 1 moves toward the spring end under the action of the thrust.

As shown in Figure 1, when the pressure at the fluid inlet is not enough to push the spool or push the spool to move to the spring end less than the opening distance a of the spool, the fluid annular space A at the spool 1 is not connected to the fluid inlet P1 and the fluid outlet P2, the valve is in a closed state, and the upper side wall of the valve body seals the fluid outlet.

As shown in Figure 2, when the pressure at the fluid inlet pushes the spool to move to the spring end for a distance greater than the opening distance a of the spool, the fluid at the fluid inlet P1 and the fluid outlet P2 communicate through the fluid annular space A at the spool 1, and the fluid passes through the fluid Outlet P2 flows out. This is when the valve is open.

As shown in Figure 3, when the fluid pressure at the fluid inlet P1 continues to increase, the thrust on the valve core 1 at the pressure chamber C will further increase, and the valve core 1 will continue to be pushed to the spring end. When the upper end surface of the valve core 1 and the valve When the end faces of the sleeve 4 are in contact, the fluid annular space A at the spool 1 returns to the state of being disconnected from the fluid inlet P1 and the fluid outlet P2, and the lower cylindrical surface of the spool 1 blocks the fluid inlet P1 and the fluid outlet P2. At this time, The lower side wall of the valve body seals the fluid inlet, the fluid inlet P1 and the fluid outlet P2 are not connected, and the valve is in a closed state.

When the fluid inlet pressure P1 keeps decreasing, the spool 1 moves downward under the action of the spring 3, and when the pressure at the fluid inlet continues to drop to the point where the valve spool moves to the spring end less than the spool opening distance a, the spool The fluid annular space A at 1 is not connected to the fluid inlet P1 and the fluid outlet P2, and the valve is closed. When the pressure at the fluid inlet continues to decrease enough to push the valve core 1 to overcome the downward pressure of the spring 3, the lower end surface of the valve core 1 contacts the valve body 2, and all parts of the valve return to the initial state (that is, the state in Figure 1).

Note: The power to push the valve core to move up and down is the pressure formed by the fluid pressure on the contact surface of C chamber.

The specific embodiments described herein are only examples to illustrate the spirit of the present invention. Those skilled in the technical field to which the utility model belongs can make various modifications or supplements to the described specific embodiments or adopt similar methods to replace them, but they will not deviate from the spirit of the utility model or go beyond the appended claims defined range.

Claims (4)

1. a self-powering type segmentation pressure controlled valve, comprise valve body (2), it is characterized in that, sliding cavity (D) is provided with in described valve body (2), one end sidewall of sliding cavity (D) is provided with fluid output (P2), the other end sidewall of sliding cavity (D) is provided with fluid inlet (P1), spool (1) is provided with in sliding cavity (D), spool (1) middle part is provided with circumferential circular groove (A), sliding cavity (D) one end is provided with pressure chamber (C), the other end is provided with valve base piece, spool (1) one end is offseted by spring (3) and valve base piece, pressure chamber (C) is communicated with fluid inlet (P1) by inlet opening (B).

2. a kind of self-powering type segmentation pressure controlled valve according to claim 1, it is characterized in that, described valve base piece comprises the valve pocket (4) being arranged on sliding cavity (D) end, spring seat (5) is provided with in valve pocket (4), spring seat (5) one end passes valve pocket (4), the other end offers the kerve establishing spring (3) for card, and one end that spool (1) and spring (3) offset offers the kerve establishing spring (3) for card.

3. a kind of self-powering type segmentation pressure controlled valve according to claim 2, is characterized in that, described valve pocket (4) is provided with snap ring (6).

4. a kind of self-powering type segmentation pressure controlled valve according to claim 3, is characterized in that, the diameter of described pressure chamber (C) is less than the diameter of spool (1).