US3735774A

US3735774A - Differential gas lift valve apparatus

Info

Publication number: US3735774A
Authority: US
Inventors: D Chenoweth
Original assignee: Baker Oil Tools Inc
Current assignee: Baker Hughes Oilfield Operations LLC
Priority date: 1968-11-25
Filing date: 1970-11-25
Publication date: 1973-05-29
Anticipated expiration: 1990-05-29
Also published as: US3592561A

Abstract

A well bore gas lift valve apparatus for controlling elevation of well bore liquids through a tubing string to the surface of the well bore. A main pressure differential valve controls the feed of gas from the tubing-casing annulus into the tubing string, the main valve containing a pilot pressure differential valve that also controls the gas feed from the tubing-casing annulus into the tubing string. The pilot or normal high differential pressure valve opens to admit gas to the tubing string on reduction of the casing-to-tubing differential pressure. This action further reduces the casing-to-tubing differential pressure, causing opening of the main valve, both valves then being open. The pilot valve first opens, assisting opening of the main valve. The main valve first closes, assisting closing of the pilot valve.

Description

United States Patent 91 Related US. Application Data Chenoweth [4 May 29, 1973 [5 DIFFERENTIAL GAS LIFT VALVE 2,646,062 7 1953 Nixon ..137/ 155 APPARATUS [75] Inventor: David V. Chenoweth, Houston, Tex. Examiner-Alan Cohan Attorney-Bernard Kriegel and Kendrick, Subkow & 73] Asslgneez Baker Oil Tools, Inc., City of Com- K i l merce, Calif.

22 Filed: Nov. 25, 1970 [571 ABSTRACT 2 App] 2 4 A well bore gas lift valve apparatus for controlling elevation of well bore liquids through a tubing string to the surface of the well bore. A main pressure differential valve controls the feed of gas from the tubing-casing annulus into the tubing string, the main valve containing a pilot pressure differential valve that also controls the gas feed from the tubing-casing annulus into the tubing string. The pilot or normal high differential pressure valve opens to admit gas-to the tubing string on reduction of the casing-to-tubing differential pressure. This action further reduces the casing-to-tubing differential pressure, causing opening of the main valve, both valves then being open. The pilot valve first opens, assisting opening of the main valve. The main valve first closes, assisting closing of the pilot valve.

15 Claims, 4 Drawing Figures 1 DIFFERENTIAL GAS LIFT VALVE APPARATUS This application is a division of my application for Differential Control Gas Lift System, Ser. No. 778,721, filed Nov. 25, 1968, now US. Pat. No. 3,592,561.

The present invention relates to subsurface well bore valve apparatus, and more particularly to differential gas lift valve apparatus used to inject relatively high pressure gaseous fluid into a tubing string disposed in a well bore, for the purpose of elevating the liquid in the tubing string to the surface or top of the well bore.

Under some well conditions, gas lift equipment used for elevating liquid through the tubing string to the top of the well bore does not operate properly or efficiently. The gas lift valve may open at the desired pressure differential between the gas pressure in the tubingcasing annulus and the pressure in the tubing string, but the gas lift valve does not close upon the arrival and discharge of the slug of liquid at the top of the well bore. For the gas lift valve to close, the tubing pressure must reduce to a certain level below the tubing-casing annulus pressure to provide a required valve closing differential pressure. The failure of the valve closing differential pressure to be realized may also present itself where the tubing-casing annulus pressure is reduced excessively, as by low deliverability of gas into the annulus, by the presence of a small diameter casing in the well bore, or by borderline supply gas pressure.

It is desirable for a large port area to be present in the differential valve mechanism through which the gas under pressure can flow, in order for efficient ballistic lifting to occur. Such large part area provides a high flow rate of gas, and where such high flowrate is coupled with the presence of wet gas in the tubing-casing annulus, and further with the necessity for lifting the liquid through comparatively long tubing strings, valve closure is prevented after the desired quantity of the liquid has been discharged at the top of the well bore.

By virtue of the present invention, a large gas lift pressure in the tubing string to the point at which the low-set differential main gas lift valve will open, so that the gas flowing therethrough will combine with the gas flowing through the high-set differential pilot valve and assist the elevation of the slug of liquid in the tubing string to the top of the well bore. When the pressure in the tubing string drops to a certain value, the low-set pressure differential main valve will close, but the highset pressure differential pilot valve will remain open. The closing of the low-set pressure differential main valve will reduce the flow of gas into the tubing string and will reduce the pressure therewithin to the point at which the high-set pressure differential pilot valve will also close. Thus, the high-set pressure differential pilot valve assists the low-set pressure differential main valvev to open; whereas, the low-set pressure differential main valve port area is provided through which the gas can 4 enter the tubing string for the purpose of creating high flow of gas for efficient lift of the slug of liquid in the tubing string to the top of the well bore. Despite the presence of such large port areas, and even in the presence of wet lifting gas and long tubing strings, the valve device will still close at the required valve closing differential. This will occur despite the fact that the large rate of gas flow through the tubing string will increase the pressure in the tubing string to the point at which' the gas lift valve mechanism would otherwise remain in i an undesired open condition.

More specifically, the invention contemplates the provision of main and pilot gas lift valves at the gas injecting point in the tubing string, which may consist of two differential gas lift valves. The pilot gas lift valve is set to operate at a normal, comparatively high pressure differential, while the main gas lift valve is set to operate at a very low pressure differential; that is to say, the high-set pressure differential pilot valve will open and will close when the tubing pressure is at a certain value compared to the tubing-casing annulus pressure; whereas, the very low differential pressure or main valve will open and will also close when the tubing pressure is at a much higher pressure. The high-set differential pilot gas lift valve will first open to allow gas to flow into the tubing string, such flow of gas elevating the valve assists the high-set pressure differential pilot valve to close. The two differential valves provide a large combined port area with improved operating characteristics to secure efficient ballistic lift of the slug of liquid in the casing string, and such improved operating characteristics of the system are of particular advantage in wells where wet gas must be used for effecting lifting ofthe slug in long tubing strings. It is also effective where the tubing-casing annulus pressure may drop because of low deliverability of gas thereto.

This invention possesses many other advantages, and has other purposes which may be made more clearly apparent from a consideration of a form in which it may be embodied. This form is shown in the drawings accompanying and forming part of the present specification. It will now be described in detail, for the purpose of illustrating the general principles of the invention; but it is to be understood that such detailed description is not to be taken in a limiting sense, since the scope of the invention is best defined by the appended claims.

Referring to the drawings:

FIG. 1 is a diagrammatic view of a differential system embodying the invention;

FIG. 2 is a longitudinal section through the pilot and main gas lift valves embodied in the system disclosed in FIG. 1 and disposed in closed condition;

FIG. 3 is a view similar to FIG. 2, with the pilot valve in open condition; and

FIG. 4 is a view similar to FIG. 2, with both the pilot and main valves in open condition. l

The differential gas lift system disclosed in the drawings as illustrative of the invention is presented diagrammatically in FIG. I. An oil well W has a casing string B therein, with fluid from a deep storage well C capable of passing through casing perforations D to the casing interior. A well packer E may be set in the casing string above the perforations and a tubing string T is disposed in leak-proof relation to the packer so thatthe well fluid can flow upwardly through the tubing string to the top of the well bore, the tubing string extending in sealed relation through a casing head G and into a production line H under the control of a surface valve J. In some instances, the well packer need not be used, the gas from the storage well C passing into the casingtubing annulus K and to the top of the well bore. A suitable mechanism (not shown) is located in the tubing string T to control the flow of water from the well C into the tubing string T, this water being removed when it reaches a certain elevation in the tubing string, as described hereinbelow.

gas lift As specifically disclosed in the drawings, main and pilot gas lift valves R, S are mounted on the tubing string closely adjacent to the well packer E, these gas lift valves controlling the injection of gas from the casing-tubing annulus K into the tubing string, the gas being supplied from a-suitable compressor or supply line through the gas line L into the upper portion of the casing string, there being a suitable valve M for controlling such flow of gas. The pilot gas lift valve S is set to open at a relatively high casing annulus-tubing pressure differential; whereas, the main gas lift valve R is set to open at a substantially lower casing annulus-tubing pressure differential.

The differential gas lift valve mechanism includes a fitting 20 suitably secured, as by welding, to the exterior of the tubing string and having its internal passage 21 communicating with the interior of the tubing string T through a port slot 22. The lower portion 23 of the fitting is internally threaded for threaded attachment of a differential gas lift housing 24 thereto, this housing having a cylindrical valve seat 27 adapted to be closed by the upper valve head portion 28 of a main piston valve member 29 slidably mounted in the inner bore of the housing below a plurality of side chokes or orifices 30 opening through the wall of the housing 24 below the valve seat 27. Upward movement of the piston valve member 29 is limited by engagement of its shoulder 31 with a companion downwardly facing shoulder 32 on the housing, at which time the valve head 28 will be disposed within the cylindrical seat 27, leakage of fluid between the head and seat being prevented by a suitable side seal ring 33 mounted in the head and sealingly engaging the valve seat 27. When the valve head is sealingly engaged with the seat, the fluid pressure in the tubing string can act in a downward direction over the area of the valve head.

The main piston valve member 29 is shiftable downwardly to a position in which its valve head 28 is completely removed from the valve seat 27, opening the chokes to the passage of gas from the tubing-casing annulus K through the valve seat 27 and into the tubing string T. Downward movement of the piston valve is limited by engagement of a downwardly facing piston shoulder 35 with a suitable stop ring 36, in the form of a split snap ring, mounted within an internal groove 37 in the lower portion of the valve housing 24. Such downward shifting of the valve head occurs as a result of the combined action of the fluid pressure in the tubing string acting downwardly over the area of the piston valve 29 and a tension spring 38, the upper end of Y which is connected to the piston valve 29 through a pilot valve piston member 60 movable in the main valve member 29, the lower end of the spring being suitably connected to a spring anchor member 39 welded, or otherwise attached, to the exterior of the tubing string T, the spring being protected by a suitable enclosure 40. When the piston valve member 29 is in its downward or full port opening position, the spring 38 may have very little tension in it.

As stated above, a pilot piston valve member 60 is embodied in the main valve member 29, the latter functioning as a housing for the pilot piston valve member. The main valve member has an upper passage 61 therethrough providing a cylindrical valve seat 62 adapted to be closed by the upper valve head portion 63 of the pilot piston valve member, which is slidably mounted in the inner bore 64 of the main valve member below the pilot valve head 63 is sealingly engaged with the seat 62, the fluid pressure in the tubing string T can act in a downward direction over the area of the pilot valve head.

The pilot piston valve member 60 is shiftable downwardly to a position in which its valve head 63 is completely removed from the valve seat 62, opening the chokes 65 to the passage of gas from the tubing-casing annulus K which flows through

side ports

30, 69 in the housing 24, through the chokes 65 and through the valve seat 62 into the tubing string T. Downward movement of the pilot piston valve member is limited by engagement of a downwardly facing piston shoulder 70 with a suitable stop ring 71, in the form of a split snap ring, mounted within an internal groove 72 in the lower portion of the main valve member. Such downward shifting of the valve member 60 occurs as a result of the combined action of the fluid pressure in the tubing string T acting downwardly over the area of the pilot position valve and the tension spring 38. The upper end of this tension spring is connected to a depending stem portion 73 of the pilot piston valve member, its lower end, as described above, being connected to the spring anchor member 39. The spring is tending to pull the pilot piston valve member 60 downwardly to an open position until it engages its stop ring 71, whereupon the spring exerts a force on the main piston valve member 29 tending to urge it to a position removing its head 28 from the cylindrical valve seat 27 of the housing 24, for the purpose of opening the chokes or orifices 30 in the housing to the passage of fluid from the tubing-casing annulus K into the seat 27 and tubing string T.

Assuming the pilot valve member 60 and the main valve member 29 to both be in the closed position, as disclosed in FIG. 2, the gas pressure P in the tubingcasing annulus K acts in an upward direction over the area A, of the pilot piston valve, which area is much greater than the area A of the upper valve head portion 63 of the pilot piston valve. When the pilot piston valve is closed, the gas pressure P is also acting in a downward direction over the annular area A of the large diameter portion 75 of the pilot piston valve, which is the area between the cylindrical valve seat 62 and a larger diameter surface of the cylindrical portion 64 of the main valve member 29 in which the pilot piston slides. This pressure is designated P, in the drawings (FIG. 4). When the pilot valve S is in the closed condition, the gas pressure can still pass through the chokes 30 to the interior of the main valve member 29 above the piston shoulder having the area A and act downwardly on the pilot piston valve 60. The gas pressure acting over this area A, makes the resultant area over which the gas pressure acts, with the valve S in the closed condition, the same area A, as the area A, of the seat of the pilot portion of the gas lift valve; that is, A A A,,.

head portion 28 of the main piston valve 29. When the main valve R is closed, the gas pressure is also acting in a downward direction over the annular area A of the large diameter piston portion, which is the area between the cylindrical valve seat 27 and the larger diameter surface of the cylindrical portion 42 of the housing in .WhiCh the main piston 29 slides. When the main valve R is in the closed condition, the gas pressure can still pass through the chokes 30 to the interior of the housing 24 above the piston shoulder having the area A and act downwardly on the main piston valve. The gas pressure acting over this area A makes the resultant area over which the gas pressure acts, with the main and pilot valves in the closed condition, the same area A,,,, as the area A,,,, of the seat of the gas lift valve;

Considering first the pilot valve S, when it is in the closed condition, the tubing pressure P, is acting downwardly over the area A,,, tending to shift the piston valve 60 to open position. The gas pressure P, in the tubing-casing annulus K is acting upwardly over the area A A,., or A, tending to maintain the pilot piston valve in the closed condition. The spring 38 is pulling the pilot piston valve 60 in a downward direction, supplementing the force of the tubing pressure P, and tending to shift the valve S to open position. When the liquid level in the tubing string T has risen sufficiently, so that its downward force on the pilot piston valve 60, supplemented by the spring force, exceeds the force of the gas pressure P, acting upwardly on the pilot piston valve 60, the latter will be shifted downwardly to an open condition, as disclosed in FIG. 3, and the gas under pressure can then flow through the open ports or chokes 65 and through the valve seat 62, continuing through the tubing port 22 to the interior of the tubing string, commencing the lifting of the slug or column of liquid ahead of it to the top of the well bore. The gas pressure P, within the main valve 29 on the downstream side of the orifices 65, which will be less than the gas pressure P, in the tubing-casing annulus K, be.- cause of the throttling action of the orifices 65, will then be acting in a downward direction on the pilot piston valve 60 over its full area A,,, this force being supplemented by the force of the spring 38 to maintain the pilot piston valve member 60 in the open condition. As

the slug of liquid is discharged at the top of the well bore, the flow of gas through the orifices 65 accelerates, the gas pressure P, on the downstream side of the orifices 65 and acting downwardly on the pilot piston valve 60 decreasing, until it and the spring 38 are insufficient to hold the pilot valve 60 in the downward or valve opening condition, the greater gas pressure P in the tubing-casing annulus K actingupwardly over the area A, of the piston valve and shifting it to the closed condition.

By making the area A over which the gas pressure P, acts, with the valve in the open condition, greater than the area A, over which the tubing pressure P, acts, when the valve 60 is in the closed condition, the area A, of the orifices or chokes can be made much greater, since the large piston area A compensates for the smaller pressure drop created by the enlarged chokes or orifices 65 of area A There is thus provided a differential valve that will open and close atapproximately the same differential pressure.

The main valve R functions in essentially the same manner as the pilot valve S. Assuming the pilot piston valve 60 to have shifted to its opened condition, such as disclosed in FIG. 3, and with the main valve R still closed, the gas pressure in the tubing-casing annulus K is acting upwardly over the main piston valve, tending to maintain it in the closed condition. The spring 38 is now acting on the main piston valve 29 in a downward direction, since the pilotpiston valve 60 has engaged the stop ring 71, and is supplementing the force of the tubing pressure acting downwardly on the main piston valve and tending to shift the latter downwardly to open position. When the pressure in the tubing string has risen sufficiently, as described hereinbelow, so that its downward force on the main piston valve 29, supplemented by the spring force, exceeds the force of the gas pressure acting upwardly on the main piston valve, the latter will be shifted downwardly to an open condition (FIG. 4), and the gas under pressure can then flow through the open housing ports 30, through the housing valve seat 27, and through the tubing port 22 to the interior of the tubing string T, to assist the gas flowing through the open pilot valve portion S of the apparatus in lifting the slug or column of liquid ahead of it to the top of the well bore. As in connection with the pilot piston valve, the gas pressure P,,,, within the valve housing 24 on the downstream side of the orifices 30, which will be less than the gas pressure P, in the tubing-casing annulus K, because of the throttling action of the orifices 30, will then be acting in a downward direction on the piston valve 29, this force being supplemented by the force of the spring 38, which, at this time, can be rather low to maintain the main piston valve member in the open condition. However, as the slug of liquid is discharged at the top of the well bore, the flow of gas through the orifices 30 accelerates, the gas pressure P,,,, on the downstream side of the orifices and acting downwardly on the main piston valve 29 decreasing until it and the spring 38 are insufficient to hold the main valve R in an open condition, the greater gas pressure P in the tubing-casing annulus K shifting the main piston valve 29 to its closed condition.

The pilot and main gas lift valves S, R disclosed have a very desirable characteristic of large orifice ports 65,

30 disposed therethrough to permit a large flow rate of gas into the tubing string T when the valves are in the open position, which results in efficient ballistic lift of the liquid slug in the tubing string to the top of the well bore. Such, large orifice ports can be used becau se of the making of the areas of the

piston valve members

29, 60 over which the tubing-casing annulus gas pressure P, acts greater than the area over which the tubing pressure P, acts. In some well installations, the tubing pressure P, will not drop sufficiently to close a single differential valve, since the tubing pressure does not reduce to the point at which the differential pressure increases to the valve closing condition asthe slug of fl'uid is discharged at the surface of the well bore. By virtue of the present invention, the difficulty is solved in that a large port area is provided to allow high gas rates of flow into the tubing string, while assurance is had that each gas lift valve will close at the required valve closing differential pressure.

In place of a single differential gas lift valve with a large port area being used, a plurality of differential valves, such as the main valve R and pilot valve S, are employed as disclosed in the drawings. The total desired orifice port area is divided between the main valve R and the pilot valve S. As an example, the area A through the orifices 65 of the pilot valve may be about one-third of the total required area; whereas, the area A of the orifice ports 30 of the main valve are about two-thirds of the required total area. Thus, the two valves, when open, act together to provide the desired large total orifice area through which the gas is injected into the tubing string for efficient ballistic lift. The pilot differential gas lift valve S is set to open and close at a relatively high pressure differential; whereas, the main gas lift valve R is set to operate at a lower pressure differential. As the liquid level in the tubing string T rises, with both gas lift valves closed, the highset differential pilot valve S will open first (FIG. 3), and such opening pressure may be at the desired tubing pressure P, build-up. When the high-set differential pilot valve S opens, gas will flow through its ports 65 and into the tubing string T to begin elevating the slug of liquid in the tubing string, but, at the same time, also increasing the fluid pressure P, in the tubing string, causing the annulus-tubing pressure differential to decrease below the setting of the low-set differential main gas lift valve R, such main valve then opening (FIG. 4). As a result, both the pilot and main gas lift valves S, R are now open and the tubing-casing annulus gas is passing through the combined areas of the ports or orifices of the two valves into the tubing string for efficiently lifting the slug of fluid in the tubing to the top of the well bore. During discharge of the liquid slug at the top of the well bore, the tubing pressure P, progressively decreases, and when it reaches a value below the tubing-casing annulus pressure P that provides the required differential for closing the low-set differential main valve R, such valve will close. The gas can then flow only through the high-set differential pilot gas lift valve S through its ports 65 of a lesser area than the combined areas of both differential gas lift valves, not only reducing the gas injected through the high-set differential pilot gas lift valve S, but also the pressure in the tubing string T. When such pressure reduces sufficiently, the pilot gas lift valve S will close.

The foregoing cycle of operation is repeated intermittently. Assuming both valves to be closed, the highset differential pilot gas lift valve S will first open, and such opening will effect opening of the low-set differential main valve R. When the tubing pressure is decreased as a result of discharge of theslug of liquid at the top of the well bore, the low-set differential main valve R first closes, and such closing effects a further reduction of the pressure in the tubing string to the point at which the high-set differential pilot valve S closes. Thus, the high-set differential pilot valve S opens and triggers the low-set differential main valve R to open, the low-set differential main valve R first closing and triggering the high-set differential pilot valve S to close.

In the event that well conditions are such that back flow of fluids from the tubing string T into the tubingcasing annulus K is to be prevented, a check or oneway valve arrangement is provided in the housing. As specifically disclosed, a ball check valve element 80 is shiftable downwardly into engagement with an upwardly facing valve seat 81 in the housing when both the pilot and main valves are in the open condition, and in the event that the pressure P, within the tubing string is greater than the pressure in the tubing-casing annulus. However, when both valves R and S are closed, as illustrated in FIG. 2, the ball valve element 80 rests upon the upper end of the upper valve head portion 28 of the piston valve member 29. This head portion has a by-pass notch or passageway 82 formed therein extending downwardly to a small extent from its upper end, so that, regardless of the fact that the ball valve element is engaging the upper end of the valve head 28, the tubing pressure can still pass through the notch 82 into the valve seat 62 for action upon the valve head portion 63 of the pilot piston valve member 60.

With the main valve in the closed condition, as disclosed in FIGS. 2 and 3, the ball valve member 80 is prevented from engaging the valve seat 81, so that the tubing pressure can still act in a downward direction on the main valve head portion 28, urging the main piston valve member to its open condition in concert with the spring 38, after the pilot piston valve member has engaged the stop ring 71. With the pilot piston valve open, as disclosed in FIGS, the gas under pressure can flow through the

ports

30, 65 and upwardly through the valve seat 62, elevating the ball valve member within the housing 24 and the fitting 20, the port slot 22 being too narrow to permit passage of the ball valve element into the tubing string. The ball valve element will be in essentially the same condition when bot valves are open, as illustrated in FIG. 4,

I claim:

1. In valve apparatus: a valve housing having an inlet, an outlet, a fluid passage between said inlet and outlet, and a main valve seat surrounding said passage; a main valvemember shiftable in said housing into and from engagement with said seat, said main valve member being responsive to fluid pressure externally of said housing to be shifted by such fluid pressure toward engaged position with said main valve seat, said main valve member having a pilot passage communicating with said inlet and outlet and a pilot valve seat surrounding said passage; a pilot valve member shiftable in said main valve member into and from engagement with said pilot seat, said pilot valve member being responsive to said fluid pressure externally of said housing to be shifted by such fluid pressure toward engaged position with said pilot seat; said housing having a check valve seat; a valve element engageable with said check valve seat to prevent fluid from flowing from said outlet to said inlet; means on one of said valve members engaging said valve element to prevent its engagement with said check valve seat when said main valve member engages its companion seat; and means for enabling the pressure of fluid in said outlet to act upon said pilot valve member when said pilot valve member engages said pilot seat.

2. In valve apparatus as defined in claim 1; wherein said means for enabling the pressure of fluid in said outlet to act upon said pilot valve member comprises a bypass passageway for fluid around said valve element.

3. In valve apparatus as defined in claim 1; wherein said means for enabling the pressure of fluid in said outlet to act upon said pilot valve member comprises a bypass passage in said main valve member permitting flow of fluid around said valve element to said pilot valve member.

4. In valve apparatus as defined in claim 1; wherein said means engaging said valve element to prevent its engagement with said check valve seat is on said main valve member.

5. In valve apparatus as defined in claim 1; wherein said means engaging said valve element to prevent its engagement with said check valve seat is on said main valve member; said means for enabling the pressure of fluid in said outlet to act upon said pilot valve member comprising a by-pass passage in said main valve member permitting flow of fluid around said valve element to said pilot valve member.

6. In valve apparatus: a valve housing having a single central unobstructed passage and an inlet communicable with said passage, said housing having a valve seat surrounding said passage; a main valve member shiftable in said housing between a closed position engaging said seat and an open. position disengaged from said seat and clear of said passage to fully open the same, said main valve member being responsive to fluid pressure externally of said housing for shifting by said fluid pressure toward closed position engaging said main valve seat; said main valve member having a central unobstructed pilot passage communicable with said single central passage, a pilot valve seat surrounding said pilot passage, and a pilot inlet communicable with said pilot passage; a pilot valve ,member shiftable in said main valve member between a closed position engaging said pilot seat and an open position disengaged from said pilot seat and clear of said pilot passage to fully open the same, said pilot valve member being responsive to said fluid pressure externally of said housing for shifting by said fluid pressure toward closed position engaging said pilot seat.

7. In apparatus as defined in claim 6; said housing inlet comprising one or more orifices to throttle fluid flow therethrough and produce a pressure drop therethrough; said pilot inlet comprising one or more orifices to throttle fluid flow therethrough and produce a pressure drop therethrough.

8. In apparatus as defined in claim 6; said housing inlet comprising one or more orifices to throttle fluid flow therethrough and produce a pressure drop therethrough extending from the exterior of said housing to the interior of said housing on the upstream side of said housing seat; said pilot inlet comprising one or more orifices extending through said main valve member to throttle fluid flow therethrough and produce a pressure drop therethrough from the exterior of said main valve member to the interior of said main valve member on the upstream side of said pilot valve seat.

9. In apparatus as defined in claim 6; and supplemental means exerting a force on said valve members tending to shift said valve members toward open position.

Ill

10. In apparatus as defined in claim 6; and supplemental means exerting a force on said valve members tending to shift said valve members toward open position, said supplemental means being located in a position removed from the path of fluid flow through said housing.

11. In valve apparatus: a valve housing having a first inlet, a first outlet, a first fluid passage between said first inlet and first outlet, a main valve seat surrounding said passage, said inlet comprising one or more chokes to throttle fluid flow therethrough and produce a pressure drop therethrough; a main valve member shiftable in said housing into and from engagement with said seat, said main valve member being responsive to fluid pressure externally of said housing for shifting by such fluid pressure toward engaged position with said main valve seat, said main valve member having a second inlet extending therethrough, a second outlet, a second fluid passage between said second inlet and second outlet and communicable with said first fluid passage, said main valve member having a pilot valve seat surrounding said second passage and located between said second inlet and second outlet, said second inlet comprising one or more chokes to throttle fluid flow therethrough and produce a pressure drop therethrough; and a pilot valve member shiftable in said main valve member into and from engagement with said pilot valve seat, said pilot valve member being responsive to said fluid pressure externally of said housing for shifting by said fluid pressure toward engaged position with said pilot seat.

12. In apparatus as defined in claim 11; and supplemental means exerting a force on said valve members tending to shift said valve members toward open position.

13. In apparatus as defined in claim 11; and supplemental means exerting a force on said valve members tending to shift said valve members toward open position, said supplemental means being located in a position removed from the path of fluid flow through said housing.

14. In apparatus as defined in claim 6; and supplemental means exerting a force on said pilot valve member tending to shift said pilot valve member to open position and then into engagement with said main valve member to tend to shift said main valve member toward open position.

15. In apparatus as defined in claim 11; and supplemental means exerting a force on said pilot valve member tending to shift said pilot valve member to open position and then into engagement with said main valve memberto tend to shift said main valve member toward open position. I

Claims

1. In valve apparatus: a valve housing having an inlet, an outlet, a fluid passage between said inlet and outlet, and a main valve seat surrounding said passage; a main valve member shiftable in said housing into and from engagement with said seat, said main valve member being responsive to fluid pressure externally of said housing to be shifted by such fluid pressure toward engaged position with said main valve seat, said main valve member having a pilot passage communicating with said inlet and outlet and a pilot valve seat surrounding said passage; a pilot valve member shiftable in said main valve member into and from engagement with said pilot seat, said pilot valve member being responsive to said fluid pressure externally of said housing to be shifted by such fluid pressure toward engaged position with said pilot seat; said housing having a check valve seat; a valve element engageable with said check valve seat to prevent fluid from flowing from said outlet to said inlet; means on one of said valve members engaging said valve element to prevent its engagement with said check valve seat when said main valve member engages its companion seat; and means for enabling the pressure of fluid in said outlet to act upon said pilot valve member when said pilot valve member engages said pilot seat.

2. In valve apparatus as defined in claim 1; wherein said means for enabling the pressure of fluid in said outlet to act upon said pilot valve member comprises a by-pass passageway for fluid around said valve element.

3. In valve apparatus as defined in claim 1; wherein said means for enabling the pressure of fluid in said outlet to act upon said pilot valve member comprises a by-pass passage in said main valve member permitting flow of fluid around said valve element to said pilot valve member.

6. In valve apparatus: a valve housing having a single central unobstructed passage and an inlet communicable with said passage, said housing having a valve seat surrounding said passage; a main valve member shiftable in said housing between a closed position engaging said seat and an open position disengaged from said seat and clear of said passage to fully open the same, said main valve member being responsive to fluid pressure externally of said housing for shifting by said fluid pressure toward closed position engaging said main valve seat; said main valve member having a central unobstructed pilot passage communicable with said single central passage, a pilot valve seat surrounding said pilot passage, and a pilot inlet communicable with said pilot passage; a pilot valve member shiftable in saiD main valve member between a closed position engaging said pilot seat and an open position disengaged from said pilot seat and clear of said pilot passage to fully open the same, said pilot valve member being responsive to said fluid pressure externally of said housing for shifting by said fluid pressure toward closed position engaging said pilot seat.

15. In apparatus as defined in claim 11; and supplemental means exerting a force on said pilot valve member tending to shift said pilot valve member to open position and then into engagement with said main valve member to tend to shift said main valve member toward open position.