Gas lift systems and methods for producing liquids from a well

11753,913

18/126248

March 24, 2023

A method of unloading and producing liquids from a well uses a plurality of gas injection valves installed on a production tubing. The injection valves are controlled by pressure signals transmitted through a single fluid control line. A first pressure signal is applied to the control line to open the plurality of injection valves. Gas is pumped into the annulus at an injection pressure until a first pressure drop occurs in the injection pressure, the first pressure drop being indicative of gas flowing through a first, upper one of the injection valves. Pumping of gas is continued until a second pressure drop occurs in the injection pressure, the second pressure drop being indicative of gas flowing through a second, lower one of the injection valves. A second, lower pressure signal then is applied to close the first injection valve while leaving the second injection valve open.

KHOLLE Magnolia 2015, LLC (Tomball, TX, US)

KHOLLE Magnolia 2015, LLC (Tomball, TX, US)

1. A method of operating a gas injection system to unload and produce liquids from a well; wherein said gas injection system comprises: (a) production tubing adapted to convey fluid between said well and the surface; (b) a plurality of gas injection valves installed on said production tubing and adapted to control the flow of gas between an annulus surrounding said production tubing and said production tubing; and (c) a single fluid control line communicating with each of said plurality of gas injection valves; (d) wherein said injection valves each comprise: i) a valve housing having a gas inlet communicating with one of either said annulus or said production tubing, a gas outlet communicating with the other of said annulus or said production tubing, and a control fluid inlet communicating with said control line; ii) a gas flowpath from said gas inlet to said gas outlet; iii) a valve seat in said gas flowpath; iv) a valve body adapted to selectively seat on said valve seat to open and shut said gas flowpath; v) a resilient element biasing said valve body on said valve seat such that said injection valve is normally shut; and vi) an actuating chamber communicating with said control fluid inlet and isolated from said gas flowpath; vii) wherein said resilient element is responsive to fluid pressure introduced into said actuation chamber through said control line such that said valve body may be selectively seated on said valve seat by sequentially increasing and decreasing pressure in said actuating chamber relative to the biasing force of said resilient element; viii) wherein the biasing force of said resilient element is substantially equal in all said injection valves; and (e) wherein said method comprises: i) applying a first pressure signal to said control line to open said plurality of injection valves; ii) pumping gas at an injection pressure into one of either said annulus or said production tubing until a first pressure drop occurs in said injection pressure, said first pressure drop being indicative of gas flowing between said annulus and said production tubing through a first, uppermost one of said injection valves; iii) pumping gas into said one of said annulus or said production tubing while gas is flowing through said first injection valve until a second pressure drop occurs in said injection pressure, said second pressure drop being indicative of gas flowing between said annulus and said production tubing through a second one of said injection valves, said second injection valve being downhole from said first injection valve; iv) applying a second pressure signal in said control line, said second pressure signal being a reduction in said first pressure signal effective to close said first injection valve while leaving said second injection valve open; and v) pumping gas into said one of said annulus or said production tubing while gas is flowing through said second injection valve.

2. The method of claim 1 , wherein said method comprises: vi) pumping gas into said one of said annulus or said production tubing until a third pressure drop occurs in said injection pressure, said third pressure drop being indicative of gas flowing between said annulus and said production tubing through a third one of said injection valves, said third injection valve being downhole of said second injection valve; vii) applying a third pressure signal in said control line, said third pressure signal being a reduction in said second pressure signal effective to close said second injection valve while leaving said third injection valve open; viii) repeating steps (vi) and (vii) in respect to sequentially lower ones of said injection valves until a final pressure drop occurs in said injection pressure, said final pressure drop being indicative of gas flowing between said annulus and said production tubing through a lowermost one of said injection valves; and ix) applying a final pressure signal, said final pressure signal being a reduction in a penultimate pressure signal effective to close a next-uphole one of said injection valves while holding said lowermost injection valve open.

3. The method of claim 1 , wherein: (a) said gas injection system comprises: i) a packer between said annulus and said production tubing at a depth below said plurality of injection valves; and ii) said gas inlet of said injection valves communicates with said annulus and said gas outlet of said injection valves communicates with said production tubing; and (b) gas is pumped into said annulus and injected in said production tubing through said injection valves to produce liquids through said production tubing.

4. The method of claim 1 , wherein: (a) said gas injection system comprises: i) a plug in said production tubing at a depth below said plurality of injection valves; and ii) said gas inlet of said injection valves communicates with said production tubing and said gas outlet of said injection valves communicates with said annulus; and (b) gas is pumped into said production tubing and injected into said annulus through said injection valves to produce liquids through said annulus.

5. The method of claim 1 , wherein said resilient element in said injection valves is a piston coupled to a stack of Belleville washers.

6. The method of claim 5 , wherein: (a) said piston is mounted for reciprocating movement within said housing; (b) said valve body is coupled to said piston; (c) said actuating chamber is on a first side of said piston; (d) said injection valves comprise a washer chamber on a second side of said piston, said washer chamber communicating with a pressure equalization port in said housing whereby fluid leaking past said piston into said washer chamber can flow out of said injection valve; and (e) said stack of Belleville washers are arranged in said washer chamber, said washer stack being under compression to bias said piston in said normal position and seat said valve body on said valve seat to shut said injection valve.

7. The method of claim 6 , wherein said method comprises: vi) pumping gas into said one of said annulus or said production tubing until a third pressure drop occurs in said injection pressure, said third pressure drop being indicative of gas flowing between said annulus and said production tubing through a third one of said injection valves, said third injection valve being downhole of said second injection valve; vii) applying a third pressure signal in said control line, said third pressure signal being a reduction in said second pressure signal effective to close said second injection valve while leaving said third injection valve open; viii) repeating steps (vi) and (vii) in respect to sequentially lower ones of said injection valves until a final pressure drop occurs in said injection pressure, said final pressure drop being indicative of gas flowing between said annulus and said production tubing through a lowermost one of said injection valves; and ix) applying a final pressure signal, said final pressure signal being a reduction in a penultimate pressure signal effective to close a next-uphole one of said injection valves while holding said lowermost injection valve open.

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