Tester valve with silicone liquid spring

US 4,444,268 A
Filed: 03/04/1982
Issued: 04/24/1984
Est. Priority Date: 03/04/1982
Status: Expired due to Term

First Claim

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1. A method of flow testing a well, said method comprising the steps of:

providing an annulus pressure operated flow tester valve having a liquid spring means for returning said valve to its closed position;

maintaining said liquid spring means at substantially atmospheric pressure prior to placing said flow tester valve in said well;

lowering said flow tester valve into said well with said liquid spring means initially still at substantially atmospheric pressure as said lowering is begun;

transmitting annulus fluid pressure from an annulus of said well to said liquid spring means as said flow tester valve is lowered into said well;

locating said flow tester valve with said well at a final depth;

pressurizing said annulus an additional amount, above a hydrostatic pressure therein, sufficient to open said flow tester valve;

transmitting at least a portion of said additional amount of annulus pressure to said liquid spring means;

depressurizing said annulus to a final annulus pressure;

as said annulus is depressurized, trapping a portion of the pressure in said liquid spring means in excess of said final annulus pressure sufficient to close said flow tester valve, so that a trapped amount of liquid pressure energy trapped in said liquid spring means in excess of an amount of liquid pressure energy within said liquid spring means when said liquid spring means was at substantially atmospheric pressure is entirely obtained from transmittal of liquid pressure energy from said well annulus to said liquid spring means; and

closing said flow tester valve, upon depressurizing of said annulus, by use of said trapped liquid pressure energy.

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Abstract

A flow tester valve apparatus includes a housing having a flow passage disposed therethrough with a flow valve disposed therein for opening and closing the flow passage. A power mandrel is disposed in the housing and includes a power piston. The power mandrel is operatively associated with the flow valve for moving the flow valve from its closed position to its open position. A power port transmits pressure from a well annulus to a first side of the power piston. A first chamber is disposed in the housing and filled at least partially with a compressible liquid and a second side of the power piston is in fluid communication with the first chamber. A second chamber is disposed in the housing and includes a floating piston which divides the second chamber into a first zone and a second zone. An equalizing port is disposed in the housing for transmitting pressure from the well annulus to the second zone of the second chamber. Pressurizing and depressurizing passages communicate the first chamber with the first zone of the second chamber. A first back pressure check valve and a first flow restrictor are disposed in the pressurizing passage. A second back pressure check valve and a second flow restrictor are disposed in the second passage.

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16 Claims

1. A method of flow testing a well, said method comprising the steps of:
- providing an annulus pressure operated flow tester valve having a liquid spring means for returning said valve to its closed position;
  
  maintaining said liquid spring means at substantially atmospheric pressure prior to placing said flow tester valve in said well;
  
  lowering said flow tester valve into said well with said liquid spring means initially still at substantially atmospheric pressure as said lowering is begun;
  
  transmitting annulus fluid pressure from an annulus of said well to said liquid spring means as said flow tester valve is lowered into said well;
  
  locating said flow tester valve with said well at a final depth;
  
  pressurizing said annulus an additional amount, above a hydrostatic pressure therein, sufficient to open said flow tester valve;
  
  transmitting at least a portion of said additional amount of annulus pressure to said liquid spring means;
  
  depressurizing said annulus to a final annulus pressure;
  
  as said annulus is depressurized, trapping a portion of the pressure in said liquid spring means in excess of said final annulus pressure sufficient to close said flow tester valve, so that a trapped amount of liquid pressure energy trapped in said liquid spring means in excess of an amount of liquid pressure energy within said liquid spring means when said liquid spring means was at substantially atmospheric pressure is entirely obtained from transmittal of liquid pressure energy from said well annulus to said liquid spring means; and
  
  closing said flow tester valve, upon depressurizing of said annulus, by use of said trapped liquid pressure energy.
- View Dependent Claims (3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15)
- - 3. The apparatus of claim 1, wherein:
    - said first chamber is completely filled with said compressible liquid; and
      
      said first zone of said second chamber is filled with said compressible liquid.
  - 4. The apparatus of claim 1, wherein:
    - said first chamber is divided into a first zone and a second zone by a second floating piston;
      
      said first zone of said first chamber is filled with said compressible liquid;
      
      said second zone of said first chamber is communicated with said pressurizing passage and said depressurizing passage; and
      
      both said second zone of said first chamber and said first zone of said second chamber are filled with a substantially noncompressible liquid.
  - 5. The apparatus of claim 1, wherein:
    - an initial volume of said first chamber when said power mandrel means is in its first position is sufficiently large that said compressible liquid in said first chamber may be compressed into a final volume of said first chamber as said power mandrel means moves rapidly from its first position to its second position, said final volume being smaller than said initial volume.
  - 6. The apparatus of claim 1, wherein:
    - said second predetermined value exceeds said first predetermined value by an amount sufficient that when a pressure differential of said amount is applied across said power piston from said second side toward said first side thereof, when said power mandrel means is in its said second position, a sufficient force is exerted on said power piston to move said power mandrel means back to its said first position.
  - 7. The apparatus of claim 1, further comprising:
    - a flow impedance means, disposed in said pressurizing passage, for impeding flow of liquid through said pressurizing passage so that upon rapid pressurization of said well annulus an annulus fluid pressure in said annulus will increase faster than said annulus fluid pressure can be transmitted through said pressurizing passage to said first chamber, thereby creating a differential pressure across said power piston from said first side toward said second side thereof sufficient to move said power mandrel means from its said first position to its said second position to thereby open said flow valve means.
  - 8. The apparatus of claim 1, further comprising:
    - a flow impedance means, disposed in said depressurizing passage, for impeding flow of liquid through said depressurizing passage so that when said power mandrel means is in its said second position and said well annulus is rapidly depressurized, an annulus fluid pressure in said annulus will decrease faster than the pressure of the compressible liquid in said first chamber will decrease, thereby creating a pressure differential across said power piston from said second side toward said first side thereof greater than an amount by which said second predetermined value exceeds said first predetermined value.
  - 9. The apparatus of claim 1, wherein:
    - said floating piston means is arranged within said second chamber so that said floating piston means may move in either of two opposite directions relative to said housing to either increase or decrease a volume of said first zone of said second chamber to allow for both expansion and contraction of said compressible liquid due to pressure and temperature changes as said valve apparatus is lowered into a well.
  - 10. The apparatus of claim 1, further comprising:
    - releasable holding means, operably associated with said housing and said power mandrel means, for holding said power mandrel means in its said first position until a pressure differential across said power piston from said first side toward said second side thereof exceeds a third predetermined value, and for holding said power mandrel means in its said second position until a pressure differential across said power piston from said second side toward said first side thereof exceeds a fourth predetermined value, said fourth predetermined value being less than a difference between said first predetermined value and said second predetermined value
  - 11. The apparatus of claim 10, wherein:
    - said releasable holding means includes a radially resilient collet sleeve connected to said housing and a shoulder extending radially outward from said power mandrel means, said sleeve and said shoulder each having upper and lower tapered surfaces arranged so that when said shoulder moves past said sleeve one of said tapered surfaces of said shoulder engages one of said tapered surfaces of said sleeve and causes said sleeve to expand radially to allow said shoulder to pass therethrough.
  - 12. The apparatus of claim 1, wherein:
    - said compressible liquid is silicone oil.
  - 13. The apparatus of claim 1, wherein:
    - said flow passage is a central axial flow passage; and
      
      said flow valve means is a full opening ball valve.
  - 14. The apparatus of claim 1, wherein:
    - said power mandrel means and said flow valve means are so arranged and constructed that said flow valve means is moved from its closed position to its open position in one continuous movement simultaneous with movement of said power mandrel means from its first position to its second position in one continuous movement.
  - 15. The apparatus of claim 1, wherein:
    - an initial volume of said first chamber when said power mandrel means is in its first position is sufficiently large that said compressible liquid in said first chamber may be compressed into a final volume of said first chamber as said power mandrel means moves rapidly from its first position to its second position, said final volume being smaller than said initial volume;
      
      said second predetermined value exceeds said first predetermined value by an amount sufficient that when a pressure differential of said amount is applied across said power piston from said second side toward said first side thereof, when said power mandrel means is in its second position, a sufficient force is exerted on said power piston to move said power mandrel means back to its said first position;
      
      said apparatus further includes a flow impedance means, disposed in said pressurizing passage, for impeding flow of liquid through said pressurizing passage so that upon rapid pressurization of said well annulus an annulus fluid pressure in said annulus will increase faster than said annulus fluid pressure can be transmitted through said pressurizing passage to said first chamber, thereby creating a differential pressure across said power piston from said first side toward said second side thereof sufficient to move said power mandrel means from its said first position to its said second position to thereby open said flow valve means;
      
      said apparatus further includes a second flow impedance means, disposed in said depressurizing passage, for impeding flow of liquid through said depressurizing passage so that when said power mandrel means is in its said second position and said well annulus is rapidly depressurized, an annulus fluid pressure in said annulus will decrease faster than the pressure of the compressible liquid in said first chamber will decrease, thereby creating a pressure differential across said power piston from said second side toward said first side thereof greater than an amount by which said second predetermined value exceeds said first predetermined value;
      
      said floating piston means is arranged within said second chamber so that said floating piston means may move in either of two opposite directions relative to said housing to either increase or decrease a volume of said first zone of said second chamber to allow for both expansion and contraction of said compressible liquid due to pressure and temperature changes as said valve apparatus is lowered into a well; and
      
      said power mandrel means and said flow valve means are so arranged and constructed that said flow valve means is moved from its closed position to its open position in one continuous movement simultaneous with movement of said power mandrel means from its first position to its second position in one continuous movement.

2. A valve apparatus, comprising:
- a housing having a flow passage disposed therethrough;
  
  flow valve means disposed in said housing and movable between a closed position wherein said flow passage is closed, and an open position wherein said flow passage is open;
  
  power mandrel means, disposed in said housing, said power mandrel means including a power piston, said power mandrel means being operatively associated with said flow valve means for moving said flow valve means from its closed position to its open position upon movement of said power mandrel means longitudinally within said housing from a first position to a second position;
  
  power passage means disposed in said housing for transmitting pressure from a well annulus external of said housing to a first side of said power piston;
  
  a first chamber disposed in said housing and filled at least partially with a compressible liquid, a second side of said power piston being in fluid communication with said first chamber so that pressure from said compressible liquid is transmitted to said second side of said power piston;
  
  a second chamber disposed in said housing;
  
  a floating piston means disposed in said second chamber and dividing said second chamber into a first zone and a second zone;
  
  an equalizing passage means, disposed in said housing for transmitting said pressure from said well annulus external of said housing to said second zone of said second chamber;
  
  a pressurizing passage communicating said first chamber with said first zone of said second chamber;
  
  a first back pressure check valve means, disposed in said pressurizing passage, for allowing liquid to flow from said first zone of said second chamber through said pressurizing passage into said first chamber when a pressure in said first zone of said second chamber exceeds a pressure of said compressible liquid in said first chamber by a first predetermined value, and for preventing liquid from flowing from said first chamber through said pressurizing passage to said first zone of said second chamber;
  
  a depressurizing passage communicating said first chamber with said first zone of said second chamber; and
  
  a second back pressure check valve means, disposed in said depressurizing passage, for allowing liquid to flow from said first chamber through said depressurizing passage into said first zone of said second chamber when the pressure in said first chamber exceeds the pressure in said first zone of said second chamber by a second predetermined value, said second predetermined value being greater than said first predetermined value, and for preventing liquid from flowing from said first zone of said second chamber through said depressurizing passage into said first chamber.

16. A valve apparatus, comprising:
- an outer housing including;
  
  an upper housing adapter;
  
  a valve housing section connected to said upper housing adapter;
  
  an upper filler nipple connected to said valve housing section;
  
  a power housing section connected to said upper filler nipple;
  
  a liquid spring chamber connector connected to said power housing section;
  
  a liquid spring chamber housing section connected to said liquid spring chamber connector;
  
  a lower filler nipple connected to said liquid spring chamber housing section;
  
  a lower housing section connected to said lower filler nipple; and
  
  a lower housing adapter connected to said lower housing section;
  
  valve means, disposed in said valve housing section, and movable between open and closed positions;
  
  power mandrel means, disposed in said outer housing, and including a power piston received within a cylindrical inner bore of said power housing section, said power mandrel means being operatively associated with said valve means for movement of said valve means between its open and closed positions upon movement of said power piston within said power housing section, a lower end of said power mandrel means being slidably and sealingly received within a central bore of said liquid spring chamber connector;
  
  a power port disposed through a wall of said power housing section and arranged to be in fluid communication with an upper side of said power piston;
  
  a liquid spring chamber mandrel means having an upper end connected to said liquid spring chamber connector and a lower end received in a bore of said lower filler nipple, said liquid spring chamber mandrel means being spaced radially inward from said liquid spring chamber housing section so as to define an annular main spring chamber which is in fluid communication with a lower side of said power piston;
  
  a lower mandrel having an upper end connected to said lower filler nipple and a lower end sealingly received in a bore of said lower housing adapter, said lower mandrel being spaced radially inward from said lower housing section to define an annular equalizing chamber;
  
  a metering cartridge disposed between said lower housing section and said lower mandrel at an upper end of said equalizing chamber;
  
  pressurizing passage means, disposed through said lower filler nipple and said metering cartridge, for communicating said main spring chamber with said equalizing chamber;
  
  a pressurizing back pressure check valve disposed in said pressurizing passage means within said metering cartridge, for allowing liquid to flow from said equalizing chamber to said main spring chamber;
  
  a first time delay liquid flow restriction disposed in said pressurizing passage means within said metering cartridge;
  
  a depressurizing passage means, disposed through said lower filler nipple and said metering cartridge for communicating said main spring chamber with said equalizing chamber;
  
  a depressurizing back pressure check valve, disposed in said depressurizing passage means within said metering cartridge, for allowing liquid to flow from said main spring chamber to said equalizing chamber;
  
  a second time delay liquid flow restriction disposed in said depressurizing passage means within said metering cartridge;
  
  an equalizing port disposed through a wall of said lower housing section; and
  
  a floating piston means, disposed in said equalizing chamber above said equalizing port.

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Current Assignee
Halliburton Company
Original Assignee
Halliburton Company
Inventors
Barrington, Burchus Q.
Primary Examiner(s)
Novosad, Stephen J.
Assistant Examiner(s)
Bui, Thuy M.

Application Number

US06/354,529
Time in Patent Office

782 Days
Field of Search

166/373, 166/374, 166/319, 166/321, 166/324, 166/325, 166/332, 166/334
US Class Current

166/373
CPC Class Codes

E21B 2200/04   Ball valves

E21B 34/108   with time delay systems, e....

E21B 49/001   specially adapted for under...

E21B 49/087   Well testing, e.g. testing ...

Tester valve with silicone liquid spring

First Claim

1 Assignment

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Accused Products

Abstract

56 Citations

16 Claims

Specification

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Tester valve with silicone liquid spring

First Claim

1 Assignment

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Subscription Required

0 Petitions

Subscription Required

Accused Products

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Abstract

56 Citations

16 Claims

Specification

Subscription Required

Solutions

Use Cases

Quick Links