SA519401010B1 - Coiled tubing arrangement for wellbore unloading - Google Patents

Abstract

A wellbore unloading arrangement for removal of debris from a wellbore. The unloading arrangement includes an unloading bottom hole assembly which can inject both nitrogen and a liquid as well as draw debris into a flowbore for transmission to surface. Nitrogen injection allows unloading at greater depths. FIG. 1

Description

COILED TUBING ARRANGEMENT FOR WELLBORE UNLOADING COILED TUBING ARRANGEMENT FOR WELLBORE UNLOADING FULL DESCRIPTION BACKGROUND TECHNICAL SCOPE OF THE INVENTION: The invention, das, relates generally to devices and methods for emptying; Or clean the pits of a blister. DESCRIPTION OF RELATED ART: During the production of hydrocrionate-producing fluids from a wellbore it is often necessary to vacuum “or clean” the wellbore by removing the gall solids and fluids from the wellbore. Typically, removal of said solids and liquids is necessary after simulation.

Baker Hughes used the WEE Vac™; The Sand Vac™ which features a pressure le fluid jet pump to dislodge debris debris coupled with a debris vacuum medium to transport debris solids and liquids to the surface. General description of the invention

0 The present invention provides systems and methods for unloading fy pits using a Je high pressure fluid jet pump and debris debris unloading medium in combination with nitrogen injection. running 9 and unloading bottom hole assembly ji to remove debris in the form of solids and liquids from the wellbore. Calls is a series of laying tubes of two series of tubes

5 ll coiled tubes are placed in an outer coiled tube series. The discharge bottom Jill assembly attaches to the spillway series and includes a fluid jet pump, debris discharge medium, and a nitrogen injection tool. The injection of nitrogen during the operation of the fluid jet pump reduces the fluid density within the blister bore close to the bottom of the “ull” assembly and thus improves the efficiency of the debris discharging medium. The inventors also specified that a combination of fluid jetting and a vacuum medium (Rag

Nitrogen can allow the user to offload the well at greater depths compared to conventional techniques. Lead

The injection of nitrogen reverses the hydrostatic pressure that could otherwise hinder debris removal.

Brief description of the drawings

For an understanding of the present invention as “dol” reference is made to the following detailed description of the preferred embodiments; in combination with attached graphics; Where identical reference numbers refer to similar or similar items

Similar through the various forms of graphics and where:

Figure 1 is a lateral cross-sectional projection of an illustrative blister pit containing a degassing arrangement

Blister pit constructed Gy of the present invention.

Figure 2 is an axial cross-sectional projection of a series of laying pipes for a pit discharge arrangement

0 warts. Figure 3 is a profile of a Gy discharge bottom-well assembly of the present invention. Detailed description: Figure 1 shows an illustrative fi crater 10 drilled through the ground 12 from surface 14 downstream of a hydrocrion-bearing formation 6 1 Debris 8 1 is located in the blast pit 0 1 . Debris be 8 1 minute

5 1 Relatively typical and may include sand and excavations. The J hole discharge arrangement 20 is placed into the Jad hole 10 of deck 14 via a coiled tubing injector (not shown). Blister hole discharging arrangement 20 includes a D series tubing 22 and a discharging blister bottom assembly 24.

0 Laying tubing series 22 includes an external laying tubing series 26 specifying a flush hole 28. First and second coiled tubing series 30 are to be placed; 32 into the drill hole 28 of the outer coiled tubing series 26.

Figure 3 shows an illustrative 24 discharge downhole assembly in more detail. The discharge bed of blisters assembly includes 24 outer housing 34 with front part 36 containing injection nozzles 38 for injecting fluids into all bore 10. Fluids that can be injected through injection nozzles 8 can be supplied via the first and second coiled tubing series 30 32. in a preferred embodiment; tip is blocked

The bottom of the first convoluted tubing series 30 by means of a plug 39 to cause the fluid flowing through the first convoluted tubing series 30 to exit through a side hole 41. Vacuum ports 40 are located in the housing 34 to allow fluid and solids to enter the overflow hole 28 of the outer coiled tubing series 26 from the ull hole 10. Debris 18 will enter the inflow hole 28 of the outer coiled tubing series 26 and then to the surface 14. It can be separated

Large debris 18 is filtered so that it does not enter the bore hole 28 by a screen through the discharge ports 0. A nitrogen supply 42 and an associated fluid pump 44 are located at the surface 14 and are actively connected to the blowhole discharge arrangement 20 so that the nitrogen flows into the first coiled tubing series 30. Also A fluid supply 46 and an associated fluid pump 48 are located at deck 14 and coupled

5 Efficiently arrange the discharge of the blister pit 20 so that a fluid from the fluid supply 46 flows into the second coiled tubing series 32. The fluid from the fluid supply 46 is typically water but can be other fluids as well. Lad placed coiled tubing injection assembly (not shown) of a type well known in the art; at surface 14 and were used to inject the discharge arrangement of the blister hole 20 into the Jal hole 10 as well as remove it from the blister hole 10.

0 On Operation” The Jal Hole Discharge Arrangement 20 is placed in the wellbore 10 and lowered so that the Discharge Jill Bottom Assembly 24 is located at a desired location near the debris 18 to be removed. Nitrogen is pumped through the first inner coiled tubing series 30 to the discharge ill bottom assembly 24. A non-nitrogen liquid is pumped down the second inner coiled tubing series 32 to the discharge jal bottom assembly 24. During operation; The fluid jet pump 33 switches between series fluid injections

5 Second internal coiled tubes 32 through nozzles 38 and vacuum capacity to draw debris into hole

Flow 28 of the outer coiled tubing series 26 through the discharge ports 40. The fluid drawn asia through the injection nozzles 38 will help dislodge the debris 18 contained in the All hole 10. The displaced debris 18 can then be drawn into the flow hole 28 through the discharge ports 40. During operation to remove debris 18; Nitrogen can flow from the nitrogen source 42 to the injection nozzles 38. Nitrogen injection is preferably in ull hole 10 near the wreck 18

It can be carried out continuously during liquid injection and discharging. In addition, the jill unloading arrangement 20 can be pivoted within J-hole 10 during said operations to aid in the displacement and removal of debris 18. The inventors believed that injecting nitrogen during operation of the jet pump for fluid 33 would reduce the density of the fluid

0 fluids within the Jill hole 10 close to the downhole assembly for discharge 24; Thus the efficiency of the debris discharging medium is improved. Furthermore it; The inventors discovered efficient operation of Liquid Injection and Debris Removal (Sas) at greater wellbore depths than conventional systems.

Claims (1)

Protection Elements 1- Wellbore unloading arrangement yk (20) for removing gravel (18) from a blister pit (10) Cus The wellbore unloading full Ses arrangement (20) includes: Series running string (22) and unloading bottom hole assembly 5 (24); where the running string (22) is configured to install the unloading bottom hole assembly (24) inside the blister hole (20); and so that the unloading bottom hole assembly is loaded (24) by means of a running string (22)¢ 0 is characterized by an unloading bottom hole assembly (24) configured to inject nitrogen and liquid into the ll hole (10); The galll unloading bottom hole assembly (24) is also configured to pull the gravel (18) into the running string (22) using suction; The unloading bottom hole assembly (24) comprises a jet pump (33) which is operable to inject liquid through the nozzles (38) into the well sim (10) and thus provide suction capacity To withdraw the gravel through the vacuum ports (40) inside the flow hole (28) with the running string (22). 0 2- A wellbore unloading arrangement ill (20) according to Claim 1 where the running string gall (22) also includes: an external coiled tubing string (26) that defines a hole flush (28) along its length; the first inner coiled tubing string (30) into the flush bore (28) with the outer coiled tubing string (26); and A second internal coiled tubing string (32) inside the overflow hole (28) with the external coiled tubing string (26). 3- Wellbore unloading arrangement ill according to Clause 2 where: Nitrogen flows through the first inner coiled tubing string (5430) The liquid flows through the second inner coiled tubing string (32) 0 4- wellbore unloading arrangement ill ) 20) According to Claim 1 where the liquid is water. 5- A method for unloading the Sis pit load (10) by removing gravel (18) from the blister pit The method is characterized by the following steps: 5 Installing wellbore unloading arrangement Jill (20) Into the All (10)” wellbore unloading arrangement yall (20) has an unloading bottom hole assembly (24)¢ liquid injection into the Jill hole (10) Through the unloading bottom hole assembly (24) To expel the gravel (18) ¢ Remove the gravel (18) from the Jl hole (10) By drawing the gravel (18) into the unloading bottom hole assembly unloading bottom hole assembly (24) by suction; And injecting nitrogen into the borehole (10) through an unloading bottom hole assembly (24) near the gravel (18); Cua jet pump is provided (33) which is workable for injecting liquid into a hole Bin Jen fii dunend 5 J) ml) cond Bi 85 isi 2 ms (10) ad 25 £5 unloading bottom hole assembly (24)- 6- The method according to Claim 5, whereby installing a wellbore unloading arrangement (20) inside the wellbore (10) is also characterized by: Installing an unloading bottom hole assembly (24) inside Blistering hole with a running string 5 (22) that includes an external coiled tubing string (26) that defines a flow hole (28) and at least one internal coiled tubing string (30 7- The method according to claim 6 is also characterized by: injection of nitrogen through at least one internal coiled tubing string (30); removing Gravel (18) through the flush hole (28). ْ | A ! | iy YE = 2 TE | } {net A TEA Vos : LTTE HJNA A TR LTA VT aA ST ered \ V7 enh deny \ i ED Ley by A yr CE UR TET SALA[‎ 3 ¥ 3 ta y Cad [ SL 1 4 With me 1 ers 3 i Raba the 4 3° a Pray l a l a dh Ye Tm SETH TITE TE Toe hy T 1 3 AT PEIN ram = + bd 1 y 1 eT § Lee ah ra: LY 51 A S 1 SET AT TAKE ALL EAE SEAR HAL LISA SEAK 2 TABLE OF ELIMINATION FOR FERIA +1 A \ fu: NS a Tri the WT] ka wd y he 1 vo , i Ry . yy 1 § 3 1 fe 4 doer i 3 i 3% = % 1 ee” “oe i = my pain x a semen 3 VA a i \ 33 } TTA epee 2 | 8 Pore “yy leet EAT Ue SPREE | And the seisma pd Mess Lalba Al-Talt STE and Jal Zan Al-Ala Al-Anis Ran Array TRAE Bayed and Al-Mal-Ajd fd Amish Al-Mut Al-Qaq A-Mn / fle zara fod ead Pel TF FRE Lg Ed FT 3 0 EG #2 R7 ML 0 HE TR be RS LOTTA 35 REL fm m i ed, m ten § Frat & f= Dever § Fee sie f fon FFA te TE TR Ll RES Bb TE Te Te 1 —_ 1 0 —_ Tae, TT Ya Nt A & Fer, emt, 7 2 A H v 3 1 WN 4 v Rasa a A TN aE . . : oat no ae ¥ . 5 AH ae ge 1 vo 8 gd A kha A 213 [A bd Ain A 1 ETRE: A Po Aal Was A L Po Laa 1 which is to | 1 Balkham Li'a : 1 FRR = ; LA LA LA LAHA | LE TY e J 3 a X sO H 3 X > Be 0 R a for Hebi + : sg lm7 TA Figure A A TR ee The Saudi Authority for Intellectual Property Sweden Authority for Intellectual Property pW RE .¥ + \ A 0 § Um 5 + < Ne ge “Benaj > Aye Ki Jada Li Days TEE Bbha Nase eg + Ed - 2 - 3 .++ .* provided that the annual financial fee is paid for the patent and that it is not null and void due to its violation of any of the provisions of the patent system, layout designs of integrated circuits, plant varieties and industrial designs or its implementing regulations. »> Issued by + BB 0.B Saudi Authority for Intellectual Property > > > “+ PO Box 1011 .| for ria 1*1 uo ; Kingdom | Arabic | For Saudi Arabia, SAIP@SAIP.GOV.SA