CA1200199A - Method and apparatus for removal of downhole well debris - Google Patents

Abstract

A B S T R A C T

A method and apparatus for removing debris involves an elongate string operable to pump the debris from a well into the string. A
pumping portion of the string includes a hollow piston with a hollow, splined piston rod fixed to the upper portion of the string, above the pumping portion, and keyed to the pumping portion to transmit rotary motion from the upper portion to the debris retaining portion below the pumping portion. A hollow piston head includes a valve, advantageously a ball valve, to prevent downward fluid flow. By reciprocating the upper portion, well debris is pumped into the debris retaining portion and solid debris is trapped therein by a one-way check valve. The liquid debris, such as heavy water, continues upwardly through the string passing through the interior of the piston and into the upper portion. The upper portion selectively receives either a ported sub, in which case the liquid is recirculated back into the well or an unported sub that prevents the return of the debris to the well. An additional check valve may be located in the upper portion to retain the liquid in the upper portion and to relieve the stress on the ball valve. The check valves, removably secured within removable subs, preferably are flap valves, including a torsion spring biased flap element with the torsion spring located out of the direct path of fluid movement to decrease valve fouling.

Description

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This invention rela-tes generally to methods and apparatus for removing downhole debris such as sand, liquid .such as caustic or heavy water, sludge, fish, balls, plugs and the like.
For a great many years sand lines have been used to rernove sand and other debris from well bores. These sand lines usually involve a piston reciprocated within a cylinder through the action of a surface operated wire line connected to the piston. Conventionally the sand lines include a flapper valve at the lower end to prevent reverse flow from the sand line. This type of device is advantageous in comparison to hydrostatic clean out tools in that a large liquid head is not necessary.
While devices of this type have been known for some time, present day oil economics have generated renewed interest in what were once considered spent wells and in methods and apparatus for reactivating these wells.
One device of this general type is disclosed in U.S. patent 4,190,113 to Harrison. The Harrison structure includes a splined piston rod which allows both reciprocatory and rotary motion to be transferred from the surface to the downhole tool. Solid material is collected within a debris retaining chamber while liquid passes through the piston head along the outside of the piston rod, in contact with the cylinder wall, and outwardly through ports for return to the well bore. A
removable, gravity operated, flap valve is located at the inlet to the debris retaining charnber. In addition, a check valve is located in the piston head in the form of a resilient flap covering a plurality of apertures which extend through the piston head into the region between the piston rod and the cylinder wall.

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However, the inventor of the present invention has determined that, in use, the structures of the type disclosed in -the llarrison patent are subject to a number of shortcomings. Due to the caustic nature of the liquid located in many plugged oil wells, -the piston life is sometimes re]atively short. This is because the liquid passes around -the piston rod and is retained within the piston chamber, damaging the cylinder and piston walls. Since -this action is generally not visible -to the user and due to the often long operating periods experienced by these devices, their operating efficiency has suffered. This problem is aggravated by the use of non-metallic valve elements in connection with the piston head that tend to clog and deteriorate in the extraordinary environment within the well which may include not only caustic liquids but also sand, sludge and debris contaminated liquids.
In addition, the structure exemplified by the Harrison patent provides no means for preventing the return of the liquid to the well bore, important, for example, when the liquid debris is caustic, as well as in the cases where it may be desired to withdraw these liquids Erom the well.
For example, the inventor of the present invention has found that caustic or so called "heavy" water is prevalent in plugged oil wells in some regions of western Texas and that it is desirable to remove this water from the well. However, in many other oil fields, often including nearby wells, no such problem exists. In wells with uncontaminated water it may be unnecessary to remove the liquid during cleanou-t.
The structure disclosed by Harrison is also inefficiently prone to dumping its debris load when a gas pocket is encountered wi-thin the well bore.

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Upon exposure to a high pressure gas pocket the contents of the debris retaining chamber are blown upwardly through the pumping chamber and back outwardly through the ported region within the pumping chamber returning the debris to the well bore. In addition to the loss of the time spent collec-ting the debris in the first place, passage of the debris through the pump tends to foul the pump, making its operation less efficient or sometimes making the pump inoperable. To alleviate, to a degree, these problems it is known to make the piston head removable from the piston rod in th~ use of the ~larrison structure. However, the threaded connection between -the rod and pis~on head is an uncomplete and unreliable solution to these problems.
It is a primary object of the present invention to overcome the problems in the prior practice in this field without requiring a large hydrostatic head.
It is an object of the present invention to provide a method and apparatus for removing heavy water from debris clogged wells.
It is also an object of the present invention to provide a pumping apparatus and method for the removal of well debris which permits the separation of solid and liquid components and the selective retention of the liquid components in a region above the pump or, when desired, to allow recirculation of the liquid.
It is another object of the present invention to provide a reciprocating pump cleanout tool which prevents load dumping during a gas blowout.

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. ., It is still another objec-t of the present invention to provide a more reliable apparatus for removing well debris, including valves which operate efficiently in the ex-treme environment experiencecl downhole.
It is yet another object oE the present invention to provide an apparatus and method for removing downhole debris which prevents prolonged contact between the working surEaces of the cylinder and piston wi-th the liquids being pumped upwardly through the device to increase operating efficiency and extend part life.
It is still another object of the present invention to provide a well cleanout device with a reciprocating pump which accomplishes these objects while permitting reciprocatory and rotary motion to be transmitted from the surface to -the debris contacting lower end of the tool, enabling drilling, milling, fish retrieval and the like in conjunction with well cleanout operations.
These and many other objects of the present invention are achieved by an apparatus for removing downhole well debris including an elongate string extendable into the well and connectable to a source of reciprocatory and rotary motion. A debris retaining portion of t'ne string includes an inlet in communication with the well and an outlet. The inle-t includes a ZO debris retaining check valve. A downhole pump portion of the string is in Eluid communication with the outlet of the debris retaining chamber. The pump portion includes a cylinder, a piston, and a splinecl piston rod, the rod and piston retained for reciprocation within the cylinder.

An upper portion of the string is in fluid communication with the pump por-tion and is connectable to the source of reciprocatory and rotary mo-tion. The piston rod is telescopically received within the cylinder arld the upper portion is fixed to the piston rod -to communicate the rotary motion of -the upper portion to the debris retaining portion -through the splined rod. The piston rod and piston head include an internal passage-way establishing fulid communication between the upper portion and debris retaining portion through the pump por-tion. A check valve is arranged to permit flow through the passageway from -the pump portion to the upper portion and to prevent fluid flow in reverse direction.
In accordance with another embodiment of the present invention a method for removing downhole well debris includes the step of forming a string with a debris retaining portion, a pumping poxtion including a piston and cylinder, and a upper portion. The string is lowered into the well, with the pumping portion located above the debris retaining portion and below the upper portion, until the debris retaining portion is in proximity to the well debris. The upper portion of the string is lifted with respect to the debris retaining portion causing relative movement to occur between the piston and cylinder, pumping the debris into the debris retaining portion. The solid component of the debris is collected with-in the debris retaining chamber while the liquid component of the debris is passed through the piston in isolation from the cylinder, into the upper portion. The string is turned in the process, to loosen the debris.

0~99 The invention will rnow be-described with reference to the following drawing in which:
FIG. 1 is a partial, front elevational view of one ernbodirnent of the present invention, shown in position within a cross-sectioned well.
FIG. 2 is an enlarged, exploded view partially cross-sectioned along a cen-tral ver-tical plane throuyh the apparatus shown in FIG. 1.
FIG. 3 is a front elevational view of a ported sub useful in the embodiment shown in FIG. 1.
FIG. 4 is an exploded view of a fishing tool useful in connec-tion with the embodiment shown in FIG. 1.
FIG. 5 is an enlarged cross-sectional view taken generally along either of the lines 5-5 in FIG. 2 through the two valve subs, with the valve closed, the view being identical in either case; and FIG. 6 is a cross-sectional view taken generally along -the line 6-6 in FIG. 5.
Referring to the drawing wherein like reference characters are used for like parts throughout -the several views, a generally tubular string 10, shown in FIG. 1, is positioned within a well 12. The .string 10 is connected to a conventional surface workover rig (not shown) for reciprocating the string along the length of the well 12 and for rotating the string within the well around an axis extending parallel to the length of the string 10. The downhole end 14 of the string 10 is located in proximity to well debris 16, for example, near a plug or the bot-tom of the well 12. The string 10 may be either wire line or tubing conveyed; however, the use of tubing is preferred to facilitate the rotary motion of the string 10. The string 10 includes a debris retaining chamber 18, a pumping portion 20 and an upper portion 22 connectable to -the wire line ~3ir3~ ~

or tubing, in turn connected to a surfaca rig (not shown).
As shown in FIG. 2, the debris retaining portion 18 includes a feathering sub 24, a solid debris collection sub 26, a valve sub 28a, and a debris engaging sub 30. Each of the subs 24 through 30 is threadedly connected to its adjacent sub to enable selectlve arrangement, removal, and replacement of the various subs forming the portion 18.
The feathering sub 24 includes an upper threaded collar 32 and a -threaded, apertured plug 34. An elongate bore 36 extends centrally through the plug 34. The diameter of the bore 36 is considerably less than the internal diameter of the adjacent portions of the string 10.
The solid debris collecting sub 26 includes a pair of threaded ends 38 and 40. The threaded end 38 is securable to the threaded end 42 of the plug 34 and the threaded end 40 is releasably securable to the threaded end 44 of the valve sub 28a. The interior of the solid debris collecting sub 26 is sized to retain the debris collec~ed from -the well 12 and thus may be on the order of as long as 100 feet in length, it narmally being desired to remove the entire debris load in a single trip to the well.
However, the length of the sub 26 is controlled by the amount of liquid in the well because the pumping portion 20 must be within pumping distance of the fluid column.
The valve sub 28a, securable to the debris engaging sub 30 by its threaded end 46 and the threaded upper end 47 of the sub 30, includes a one-way valve 48 located within its interior to permit flow upwardly into the string 10 while preventing reverse flow out of the string 10. The valve 48 is preferably an upwardly opening flap valve. One hiyhly advantageous valve for this purpose, shown in FIGS. 5 and 6, is removably located within : ' the interior of -the sub 28. The valve 48 is supported atop a ledge 50 formed in the interior surface of the sub 28 and retained against upward movement by a -threaded fastener 52, convenien-tly a conventional set screw, engaging a periphera] annular depression 54 encircling the seat 56 of the valve 48. The seat 56 forms an approximatel~ semi-circular opening 58 closed by a pivo-tal flap element 60. The flap element 60 is biased -to the closed position, engaging the seat 56, by a coiled, torsion spring 62 encircling a pin 64 that mounts the element 60 for pivotal movement with respect to the seat 56. One end 66 of the spring 62 is secured to the flap element 60 while the other end 68 is secured within an appeture 70 in the seat 56.
Since the spring 62 is situated astride the opening 58 and over the seat 56, it experiences much less exposure to the flow through the sub 28.
Further protection against contamination is provided to the spring 62 and pin 64 by the upwardly directed flanges 72 located to either side of the spring 62,connected to the seat 56, and by the lateral tabs 73 of the ele-ment 60, that receive the pin 64 and sandwich the spring 62 between them-selves. In addition, a tubular bushing 74, encircled by the spring 62 as well as by the tabs 73 of the element 60, facilitates the action of the spring 62.
The debris engaging sub 30, connected to the valve sub 28a on one end, has, on the other end, an inlet 78 that admits the debris 16 into the string 10. A variety of conventional debris engaging subs may be used as the sub 30, depending on the intended use of the string 10. The drilling sub 30a, shown in FIG. 2, for example, includes a serrated lower edge 80 .3~

useful in grinding or drilling solid debris 16 to enable the particles to be sucked inwardly into the string 10. The retrieving sub 30b shown in FIG. 4, is useful for engaging and removing a lodged downhole fish 82 using a conventional engaging means (not shown) located in i-ts interior, Upon downward movement and subsequent rotation of the string 107 the sub 30b engages and is locked onto -the ou-twardly extending pin 84 of the fish 82. Any conventional debris engaging sub may be used in place of -the illustrated subs 30a and 30b for drilling, milling, retrieving fish, col-lecting junk, supplying liquid, cleaning, swabbing, bailing or the like, all well known in the art.
Located atop the debris retaining portion 18, the pumping portion 20 includes a drive sub 86 and a collar 32 threadedly connectins the sub 86 to a cylinder 88. The cylinder 88 includes a threaded end 90 engaging one collar 32 and a threaded end 92 threading onto the collar other 32. A
piston 94 is mounted for reciprocation within the sub 86 and the cylinder 88.
Specifically -the piston head 96, mounted for reciprocation in close conformi.ty to the inside walls of the cylinder 88, includes a plurality of encircling seals 98, conveniently in form of piston rings providing an occlusive seal between the piston head 96 and the cylinder wall 88. The piston rod 100, conveniently threaded into the head 96, is in the form of a splined shaft, preferably a hollow hexagonal kelly bar. An interior pas-sage 102 is formed through the piston rod and the piston head 96, providing liquid communication through the pumping portion 20. Within the passage 102, conveniently located wi-t~.in the piston head 96, a bal.l valve 104 : 25 conveniently includes a steel ball 106 contained within an enlarged or bored -, ' _g_ 11;9~

out chamber 108 and a -transverse pin 110 located between the ball 106 and the upper end of the chamber 108. The chamber 108 is closed by a replaceable annular seat 109, that conveniently threads into -the lower end of the chamber 108.
The piston rod 100 telescopes through the drive sub 86 and a broached interior surface 111 of -the portion 112 of the drive sub 86 conforms to the splined exterior configuration of the piston rod 100 to key the rod 100 to the pumping portion 20. The exterior surface 113 of the portion 112 also provides a reduced diameter fishing neck to enable a fishing tool to catch or slide over and catch the portion 112~ The upper end of the piston rod 100 i5 secured to a coupler 114, conveniently by a threaded connector, the coupler 114 in turn threadedly secured to a valve 28b, identical to the valve sub 28a secured to the bottom of the solid ~
debris collecting sub 26. The valve sub 28b double checks the debris and thereby relieves the stress on the ball valve 10~. Reciprocation of the piston 9~ pumps fluid from the well 12 upwardly through the debris retaining portion 18 and upwardly through the pumping portion 20. A very slight clearance between the piston head 96 and the cylinder 88 insures the generation of high pumping pressure while allowing a very small quanti-ty of liquid to lubricate the passage of the head 96 with respec-t to the cylinder 88. Excess liquid is ported through the joint between the rod 100 and sub 86.
The upper portion 22 includes a liquid receiving sub 116 threadedly connected to the adjacent valve sub 28b and to the r~;n;ng portion of the string 10, illustrated in the form of tubing 118. As shown in ~IG. 2, the liquid receiving sub 116 may take the form of a closed cylinder 116a, that 3~

receives any liquid passing through the pumping portion 20 and retains -that liquid above the valve sub 28b. As de.sired, the liquid receiving sub l16a may be replaced with a ported liquid receiving sub 116b, shown in FIG. 3, including a plurality o-f openings 120 venting liquid received ~,Jithin the sub 116b out~ardly to the well 12.
In accordance with the preferred method of operation, the string 10 is utilized as follows. The string lOis initially lowered into the well 12 until the downhole end 1~ contacts the debris 16 to be removed. The device 10 may be utilized to remove any downhole debris including, for exarnple, sand, liquid, heavy water, fish, balls, plugs, junk or the like. Upon contact between the string 10 and the debris 16, the string 10 is reciprocated using conventional surface apparatus (not shown). This reciprocation is transmitted from the upper portion 22 to the piston rod 100 through the coupler 114. As the result, the piston rod 100 telescopes through the drive sub 86 while the piston head 96 reciprocated along the inside surface of the cylinder 88. The vertical reciprocation is not, therefore, normally transmitted to the cylinder 88 and the remainder of the string 10 below the cylinder 88.
Thus, in response to the upward movement of the piston head 96, suction is created in the cylinder 88, and debris 16 is drawn inwardly through the inlet 18 into the debris retaining portion 18. The passage of the debris 16 into the debris collecting sub 26 is made possible by the opening of the one-way valve ~8 in the sub 28a, the valve swinging upwardly, as indicated in FIG. 2, to admi-t the solid andliquid debris. At the same time the valve 10~ is closed. Due to the length of the solid debris collecting sub 26, the solid debris separates from the liquid debris and begins to set-tle out while the liquid debris continues upwardly through the Eeathering sub 24. As the liquid encounters the lower end of the feathering plug 34 and begins to pass through the elongate bore 36, an upwardly directed force is applied to the string 10. ThiS normally prevents the string 10 from sucking itself into the debris 16 and becoming lodged -therein. The liquld -then continues upwardly into the pumping portion 20 filling the cylinder 88.
After being lifted upwardly by the surface apparatus, the upper portion 22 of the string 10 and the piston 94 move downwardly, Imder the influence of gravity and particularly due to the weight of the piston rod 100~ As the piston 94 moves downwardly, the valve 104 is opened and the pressure produced by the piston 94 closes the valve 48 in -the valve sub 28a.
This prevents the solid debris 16 from escaping from the string 10. The transverse pin 110 prevents the ball 106 from sealing against the upper i5 edge of the chamber 108, preventing the c]osing of the valve 104 and allowing the liquid to proceed upwardly through the piston rod 100 into the liquid receiving sub 116 on the piston 94 downstroke. This opens the valve 48 in the sub 28b located beneath the liquid receiving sub 116. Upon the cessation of pumping the liquid is trapped in the sub 116 by the action of the one-way valve 48 in the valve sub 28b.
If it is desired to remove the liquid debris from the well 12, the unported sub 116a is secured to the valve-sub 28b. The liquid can then either be pumped to the surface or it can be lifted to the surface with the string 10 upon completion of the job. When the contaminated liquid is collected for removal, it may sometimes be necessary to add water from -the surface to crea-te a sufficient head to permit pumping. If in subsequent operations it is not desired to remove the liquid from the well, the sub 116a may be replaced by the ported sub 116b. The sub 116b recirculates the liquid, separated from the solid debris, bac~. to the well.
During the pumping action provided by the pumping portion 20 in response -to the reciprocation of the string :L0, the string 10 can also ~e truned or rotated around its elongate axis. This rotary motion is trans-mitted through the piston rod 100 to the debris engaging sub 30 by the keyed engagement of the drive sub 86, particularly the portion 112, with the periphery of the splined piston rod 100. In the case of the sub 30a with the serrated lower edge 80 this results in the grinding of the debris 16 making it possible to subsequently suck the debris inwardly into the string 10. ~owever, in the case of the fish collecting sub 30b the rotary motion can be used to latch onto a fish, such as the fish 82 shown in FIG. 4.
The one-way valves 48 quickly snap closed to prevent reverse or downward debris flow, due to the action of torsion springs 62. The location of the torsion springs 62 prevents their fouling, since they are not located directly in the fluid path and are protected againFt dirt and grime accrual by the bushing 74 and the arrangement oE the tabs 73 and flanges 72 surrounding the spring 62. In the unlikely event that the valve 48 becomes foulecl, it can be simply removed from the valve sub 28 for repair or replacement by loosening the fastener 52.
If a gas pocket is encountered during welL cleanout operations, the contents of both the liquid receiving sub 116 and solid debris collecting sub 26 are preserved through the use of the unported sub 116a. The high pressure gas may blow the solid debris contained in the debris retaining portion 18 upwardly through the pumpiny portion 20 to collect within the liquid receiving sub 116a. This is highly advantageous in preventiny the return to the borehole of the debris that has been collected often af-ter a great deal of effort. The passaye of the debris throuyh the pumpiny portion 20 is by way of the internal passage 102 ensuring that the reciprocation of the piston 9~ is not affected hy any debris accumulation thereby preventing piston damage. In addition, the anti-fouling ball valve 104 is not prone to sticking regardless the nature of the debris passing through it. Due to the incorporation of the passage 102 the debris con-tained within the liquid receiving sub 116, does not oppose or interfere with the motion of the piston 94, since -the debris is contained in a separate chamber formed in the sub 116a, thereby increasing the life of the piston 94 and diminishing its working load, under such circumstances.
The piston 94 can also create either a manual or hydraulic jar.
The manual or mechanical jar is produced by impacting the upper end of the piston head 96 against the drive sub 86. A hydraulic jar is produced by pulling the piston head 96 against the drive sub 86, resiliently stxetching the string 10, and suddenly releasing this tension, producing a fluid surge.
Either jarring technique is useful in freeing the string 10 when it becomes stuck in the debris.
It should be understood that numerous modifications of the invention described herein can be devised by those skilled in the art which fall within the spirit and scope of -the principles of this invention. even if the invention is not practiced as specifically described herein.

Claims (36)

THE EMBODIMENTS OF THE INVENTION IN WHICH AN EXCLUSIVE
PROPERTY OR PRIVILEGE IS CLAIMED ARE AS FOLLOWS:

1. An apparatus for removing downhole well debris, comprising:
an elongate string extendable into a well, said string connectable to a source of reciprocatory and rotary motion;
a debris retaining portion, located in said string, including an outlet and an inlet in selective communication with said well, said inlet including a debris retaining check valve;
a downhole pump portion located in said string in fluid communication with the outlet of said debris retaining portion, said pump portion including a cylinder, a piston and a piston rod, said piston retained for reciprocation within said cylinder and keyed to said cylinder;
an upper portion of said string in fluid communication with said pump portion and connectable to said source of reciprocatory and rotary motion on one end and to said piston rod on the other end, said piston keyed to said cylinder to communicate the rotary motion of said upper portion to said debris retaining portion;
said portion rod and piston, including an internal passageway establishing fluid communication between said upper portion and said debris retaining portion through said pump portion; and a check valve arranged to permit flow through said passageway from said pump portion to said upper portion and to prevent fluid flow in the reverse direction.

2. The apparatus of claim 1 wherein said piston rod is a hollow kelly bar, said cylinder including an upper end conforming to the splined exterior configuration of said kelly bar.

3. The apparatus of claim 1 wherein at least one of said check valves is a flap valve, said flap valve including a valve seat and a flap element said flap element biased into a position engaging said seat.

4 The apparatus of claim 3 wherein said valve is arranged within a tubular sub, said valve having a fluid passageway of smaller size than the size of the internal passageway within said sub, said spring being a coil spring arranged over said seat out of the path of direct fluid movement through said sub.

5. The apparatus of claim 4 wherein said valve is removably locatable within said sub.

6. The apparatus of claim 1 wherein said piston includes an internal valve located in said passageway.

7. The apparatus of claim 6 wherein said internal valve is a ball valve.

8. The apparatus of claim 6 wherein said internal valve includes means for preventing the valve from seating closed during downward piston movement.

9. The apparatus of claim 6 including a seat removably threaded into said piston.

10. The apparatus of claim 1 including a check valve located at the end of said passageway atop said pumping portion.

11. The apparatus of claim 1 including a fluid collecting chamber located atop said pumping chamber in fluid communication with said passageway.

12. The apparatus of claim 11 wherein said fluid collecting chamber is connected to the upper end of said piston rod,

13. The apparatus of claim 12 wherein said fluid collecting chamber is removable from said string.

14. The apparatus of claim 1 including a ported sub removably located atop said piston rod in fluid communication with said passageway through said piston.

15. The apparatus of claim 1 including a feathering sub, said sub including a reduced diameter passageway for supplying an upward force to said string in response to the passage of liquid through said sub.

16. The apparatus of claim 1 including a drilling tool connected to the lowermost end of said debris retaining portion.

17. The apparatus of claim 1 including a fishing tool attached to the lowermost end of the debris retaining portion.

18. The apparatus of claim 1 including means for double checking said liquid upon entry into said piston.

19. The apparatus of claim 1 including a drive sub connectable to the upper end of said cylinder, said drive sub including a fishing neck on its exterior surface and a broached interior surface conforming to the splined exterior surface of said piston rod.

20. The apparatus of claim 1 including jarring means for jarring said string free of entanglement.

21. A method for removing downhole well debris comprising the steps of:
forming a string including a debris retaining portion, a pumping portion including a piston and cylinder, and an upper portion;

lowering the string into the well with the pumping portion located above the debris retaining portion and below the upper portion, until the debris retaining portion is in proximity to the well debris;
lifting the upper portion of said string with respect to a debris retaining portion, causing relative motion to occur between said piston and cylinder, to pump the debris into the debris retaining portion;
collecting the solid component of the debris within said debris retaining portion;
passing the liquid component of the debris through the piston head and piston rod of said piston, in isolation from the cylinder, and into the upper chamber; and turning the drill string to loosen the debris.

22. The method of claim 21 including the step of hydraulically jarring said string.

23. The method of claim 21 including the step of manually jarring said string.

24. The method of claim 21 including the step of retaining said liquid within said upper portion.

25. The method of claim 24 including the step of securing a hollow chamber along said string fixed to the piston rod of said piston.

26. The method of claim 25 including the step of pumping the liquid from said chamber to the surface.

27. The method of claim 25 including the step of holding said liquid within said chamber and subsequently lifting said string and said liquid from the well.

28. The method of claim 25 including the step of subsequently replacing said hollow chamber with a chamber ported to the exterior of said string to retain said liquid in the well.

29. The method of claim 21 including the step of double checking the liquid in the piston.

30. A method for removing solid and liquid downhole well debris including caustic liquid or heavy water comprising the steps of:
lowering a string into a well until the inlet end of said string is in proximity of said debris;
reciprocating a portion of said string to pump said debris into said string;
separating the solid debris from the liquid debris;
collecting said solid debris in a lower chamber;
passing said liquid debris through the interior of a reciprocating piston having a piston head and rod;
collecting said liquid in a chamber connected to the upper end of said piston rod; and removing said debris from said well.

31. The method of claim 30 including the step of pumping said liquid to the surface.

32. The method of claim 30 including the step of lifting said liquid to the surface with said string.

33. The method of claim 30 including the step of rotating said string to drill and loosen said debris.

34. The method of claim 30 including the step of withdrawing said string from the well and replacing said chamber with a ported sub.

35. The method of claim 30 including the step of adding water to the well to generate a sufficient hydraulic head to enable fluid pumping.

36. The method of claim 30 including the step of pumping said liquid through an internal passage extending through a piston head of said piston.