DE1026706B - Eruption nozzle for petroleum probes - Google Patents

Description

The invention relates to eruption nozzles, which branch off from the casing head T-pipe piece are arranged, wherein the middle leg of the T-piece forms the inflow line and of the two remaining legs with a through hole, the leg receiving the nozzle acts as a drain line serves, while the other leg is provided with a lock.

Eruption nozzle assemblies for petroleum probes are exposed to corrosive substances, so that they are corrosion-resistant Materials, e.g. B. stainless steels and other corrosion-resistant alloys Need to become. If such materials are used to fasten the actual nozzle Threads are provided, the threads are used after several under high pressure Uses from so that seepage occurs through the threaded connection. The edges of the thread then become corrosive as a result of the high speed of the seepage points flowing through Liquids destroyed quickly. Eruption nozzles must therefore be replaced on the spot can. This replacement is difficult because the thread in the nozzle housing, in the the nozzle is screwed in, the thread needs to be touched up or the nozzle housing replaced power.

This drawback is avoided according to the invention in that the nozzle is not inserted into the nozzle housing, but in the end of one in the through hole of the two aligned legs of the T-piece, preferably with play, insertable approach of the one end of the T-piece closing closure is screwed in, the nozzle being provided with at least one sealing ring through which it is sealed against the drain line.

When a repair or replacement is required then only the closure and with it the nozzle is removed and repaired or replaced, which is much easier and less expensive than repairing the thread in the nozzle housing or the replacement of the nozzle housing. The shutter and its the eruption nozzle holding tubular approach and the nozzle itself are made of ordinary steel, so that replacement requires little cost. In addition, there is no wear on the nozzle thread, because threads cut in steel are not as sensitive to wear and tear as those made of rustproof Thread made of steel or other corrosion-resistant alloys. The nozzle according to the invention forms a very secure seal that prevents seepage around the nozzle and the closure. The nozzle therefore works very reliably at high pressures.

Eruption nozzle for petroleum probes

Applicant:

George Aaron Butler,
Houston, Tex. (V. St. A.)

Representative:

Dr.-Ing. K. Boehmert and Dipl.-Ing. A. Boehmert,
Patent Attorneys, Bremen 1, Feldstr. 24

Claimed priority:
V. St. v. America 3 February 1956

Robert Eichenberg, Houston, Tex. (V. St. A.),
has been named as the inventor

Further features and advantages of the new device emerge from the following description a preferred embodiment of the invention with reference to the drawing. In the drawing is

Fig. 1 is a vertical section through a nozzle structure,

FIG. 2 is an enlarged partial section similar to FIG. 1 with the closure and part of the FIG Eruption nozzle,

3 shows an even more enlarged sectional view of the part of the device holding the nozzle.

The nozzle housing 10 (Fig. 1) is similar in shape to a flanged T-piece, its side flange is not shown in the drawing. The one provided with upper and lower flanges 11 and 12 Housing 10 has a vertical cylindrical bore 14 with a lower drain line 18 from smaller diameter and an upper extension 19 of larger diameter. The extension 19 has at its upper end a recess 20 of even larger diameter, the lower end at 21 has a tapered shoulder. The lower end of the extension 19 serves as a spring support. Above the At the upper end of the discharge line 18 there is a second Kegefechulter 22 in the bore. One of the The incoming inflow line 15 meets the bore 14 approximately in its center. The inflow line 15 is cylindrical and has a slightly smaller diameter than the bore 14.

The cover-like closure 16 has a screw bolt attached to the housing flange 11

709 957/96

Claims (5)

3 4 Flange 23, from the underside of which a cover attachment 40. The nozzle 33 has an axial nozzle bore 45 17 starts out in the bore 14 downward of such a diameter that the desired until a throttling of the flow rate is obtained above the conical shoulder 22, borrowed body extends. Above the flange 23, the flange 12 of the housing 10 is screwed the closure 16 has a cylindrical extension 24, the 5 ben with the flange 41 of a pipe transition 42 increases the strength of the lid. A drain valve connected to which one the flow from the 25 is welded to the center of the top of the extension 24 nozzle conductive pipeline. Of the screwed in. A passage 26 passes through the ver located at the outer end of the inflow line 15 Conclusion 16 from valve 25 to just below the flange can be carried out in a similar manner with the Verrohunteren Edge of the flange 23. From the passage 26 be connected io approximately head. Usually gets close If one of the nozzles extends within the cover attachment 17, a valve is installed that controls the delivery flow Bore 27 down, which regulates at its lower end to the nozzle. has an internal thread 28. The flow conveyed from the borehole through-below the flange 23 is located at the flow of the casing head and flows over the upper end of the cover attachment 17 a projection 13, 15 inflow line 15 to the nozzle. The lower surface of the flow will form a cone which has the same inclination as the conical shoulder 21 when it flows through the nozzle bore 45 and then flows out of the pipeline connected to the recess 20. A small shoulder 29 is located at the transition 42 . The one below the shoulder 13. A displaceable new nozzle structure can be used at very high pressures, locking ring 30 is within the extension 19 by 20 and up to 1000 kg / cm ² , the lid approach 17. Below this locking ring 30, he accordingly To be carried out powerfully, there is a screw must in the extension 19. The full throttle pressure also occurs in the feed spring 31, the lower end of which rests on the lower end of the flow line 15, in the bore 27 of the cover on the extension 19 and the upper end of the set 17, in which with the extension 19 in Verbinsich against the lower surface of the Locking ring 30 facing bore 14 and in the passage 26 and supports the locking ring in the widening above the bore 27. The locking ring 30 and above presses. A sealing agent is introduced into the earth, the sealing material located underneath, extension 19 via an opening 32 passing through the flange 11 above the one delivery loss and one pressure loss at the locking ring 30. Conclusion 16. The sealing ring 40 prevents seeping. The narrow shoulder 29 prevents a too far after 30 around the nozzle 33 into the drain line 18, so that the locking ring 30 moves at the top can therefore not be completely closed, the throttle flows in, out via the nozzle bore 45 and an introduction of the sealant is guaranteed at each lower end of the discharge line 18 from the time. In the axial direction, the front nozzle structure flows out and then into the transition jump 13 is longer than the recess 20, in which it flows 35 42 and the pipeline connected to it, so that the flange part and 23 in a Ab- the to any receiving device, E.g. large booths are kept from each other. The flanges containers, pipelines, etc., leads. The bolts connecting you 11 and 23 exert a tension on the flanges of the lines 15 and 18 so great that the conical surfaces are similar to the closure seal and are at full throttle pressure on each other, although the 40 can also be tensioned under high pressure conditions is not so large that the conical surfaces use. be stressed up to the crush limit. The invention can also be used with adjustable nozzles So there is no deformation of the conical surfaces. Any one used in which an adjustable valve on the base of the locking ring 30 taking place pressure has a needle that is in a vertical hole exerts a pressure on that in the extension 19 of the closure extends to the nozzle. With the similar one Sealing material and expresses the possibility of building adjustable and non-ver-sealing material in the small openings, the adjustable nozzles can adapt the invention adjustable nozzles can be found between the adjacent conical surfaces by any specialist, so that in this way a tight seal can be made. will be produced. 50 Closure, cover attachment and nozzle can be made of bore 27 has a lateral opening 44, which are made of different materials than the housing. Earth electrode Inflow line 15 of the housing 10 is aligned desires that the housing for the purpose of prolonged use can. The flow in the nozzle assembly is made of a highly corrosion-resistant material runs over the inflow line 15, the lower end consists. The nozzle and shutter, however, can go out the bore 27, nozzle bore 45 of the eruption 55 a cheap, less resistant material nozzle 33 and the lower end of the drain line 18 are made, so that these parts with less The eruption nozzle 33 is in the lower end cost to be changed on the spot the thread 28 located in the bore 27 is screwed in. can. At the same time, this is intended to result in a Ge-Die Eruption nozzle 33 has a top thread 34, causing thread wear and thread destruction outwardly directed shoulder 35, which are avoided in the 60 gentle loosening of the nozzle. the the lower end of the cover attachment 17 rests, and the selected material combination depends on the legs of the lower cylindrical section 36, the tight drive conditions and the maintenance. The tapered shoulder 22 fits into the drain line 18, although it is a preferred embodiment of the invention the lower end of the eruption nozzle 33 shown and described in the invention, but can lower end of line 18. The nozzle 33 has many changes to be made without the 65 to leave a region of the invention between shoulder 35 and cylinder section 36. concave recess 37 so that after insertion the nozzle a distance between nozzle and shoulder Latent claimsb: is available. A cylinder section 36 1st eruption nozzle for petroleum probes, which in surrounding annular groove 39 contains a sealing ring 70 of a T-pipe branching off from the casing head Piece is arranged, wherein the middle leg of the T-piece forms the inflow line and of the other two legs with a through hole, the one that receives the nozzle Leg serves as a drainage line, while the other leg with a closure is provided, characterized in that the closure (16) has a hole in the through hole (14) preferably with play insertable approach (17), at the end of which the nozzle (33) is screwed on, which in turn is provided with at least one sealing ring (40), ■ by which it is sealed against the drain line (18). 2. Eruption nozzle according to claim 1, characterized in that the extension (17) is tubular and a side bore (44) coinciding with the inflow line (15). 3. Eruption nozzle according to claims 1 and 2, characterized in that the closure (16) is designed as a cover flanged onto the T-piece, which has a conical shoulder (21) on a correspondingly conical seat in a stepped extension (19) of the bore of the T-piece rests, being in the annular space between the extension (19) and the tubular Lid attachment (17) one of a helical spring (31) loaded locking ring (30) is arranged. 4. Eruption nozzle according to claim 3, characterized in that a bore in the annular space (32) opens from the outside, through which a sealing means can be pressed into the annular space, wherein the pressure present in front of the nozzle (33) acts against the locking ring (30), so that the sealing means penetrate from the annular space in any existing leaks between the conical shoulder (21) and its seat and this can close. 5. eruption nozzle according to claims 1 to 4, characterized in that in a known manner the flow cross-section of the nozzle bore (45) from the outside through an adjustable nozzle needle is adjustable. Considered publications:
U.S. Patent No. 1,559,061;
Uren, Petroleum Produktion Engineering, 3rd edition, 1946, p. 597, Fig. 254. 1 sheet of drawings © 70Ϊ 957/96 3.58