DE1453725C - Sealing arrangement for sealing the drive motor of a submersible unit consisting of a drive motor and pump from a fluid surrounding the unit - Google Patents

Description

Sections of the sealing portion at different and 37 point in opposite axial directions Ratios and corresponding liquid levels and therefore a single one extends under Vorden. tension built-in coil spring 43 between the

In Fig. 1 has the rotating sealing bodies 38 located in a borehole, in order to press this ela-unit an electric motor 10, the upper 5 of which is connected stically against the fixed sealing body 40 end to a sealing arrangement 11. The rotating seal body 38 is. The upper end of the sealing arrangement 11 is connected to each ring seal 35 _V 36 or 37 nestles on a pump 12. About one through tightly to the shaft 18 and rotates with her. The shaft 18, which is guided by the seal assembly 11, drives through any fluid that has to pass between the motor 10 and the pump 12. io upper end 33 and the lubricant chamber 32

The sealing arrangement II has a tubular flow between the adjacent radiages Housing 13, the upper end of which with a dense surface of each sealing body 38, 40 through, processing cap 14 and its lower end with a The ring seals 35, 36 and 37 form three

Intermediate wall body 15 is connected, with a separate locking chambers which surround the shaft 18 within the second housing 16 below the intermediate 15 of the sealing cap 14. The barrier chamber wall body 15 extends and connected to it 44 is arranged above the ring seal 35. That is, while a coupling piece 17 is attached to the lower locking chamber 45 between the Ringdichtungeri 35 end of the second housing 16. These and 36 and a further locking chamber 46 between parts are axially aligned and provided by the corresponding ring seals 36 and 37. The means are connected in a sealing relationship to the lubricant chamber 32 is in direct rotation through the shaft 18 passing through them and connected to the ring seal 37.
to be stored in a sealed manner. A bore 47 in the sealing cap 14 stands

A support tube 19, the inner diameter of which is larger via a passage 48 with the locking chamber 45 in ' is than the diameter of the shaft 18 that surrounds the connection. A riser 49 is in the seal shaft 18 and is screwed into the AS cap 14 at its lower end and with the bore 47 Partition body 15 attached. Connected at its upper '. The riser 49 leads to the lower one The end of the support tube 19 is a fastening section of the lubricant chamber 32. Your.lower part 20 held, which opens in the lower end of the sealing end 50 just above the partition cap 14 is anchored. In the support tube 19 is a body 15.

Plurality of bush-like bearings 21 attached, the 3 ° A bore 51 in the sealing cap 14 is with the shaft 18 rotatably mount. Furthermore, a ball is connected to the locking chamber 46 (FIGS. 3 to 6). One bearing 22 mounted in the sealing cap 14. another riser 52 is connected to it. The

The second housing 16 has a thrust bearing 23, the lower open end 53 being substantially in the same fulfills two functions, namely the wave beneath the height of the lower end 50 of the riser 49 to be rotatable against axial pressure and the 35 is arranged.

Lubricating and cooling fluid to the engine 10 and Another bore 54 is with the locking chamber

to dissipate from this. 44 connected. The lower open end 56 of the thus

In the shaft 18 there are lateral bores 28 connected to the riser 55 in the lower section, which are essentially in connection with the axial bore 24 in connection with the lubricant chamber 32 so that the motor fluid flows through a 40 the same height as the open ends 50 and 53 the passage 29 arranged in the partition body 15 and other risers 49 and 52,
an annular passage 30 between the support. Assume that the lubricant chamber

tube 19 and the shaft 18 up or down 32, the annular passage 30, the risers can rise .. The sleeve-like bearings 21 are 49, 52 and 55 and the locking chambers 44, 45 and 46 half provided with a conventional groove. The 45 are filled with lubricant. Since the locking chamber fastening part 20 has openings 31 around the recess 44 with the external liquid in connection and exchange of lubricant between the annular one is therefore under its pressure and there continues to be the passage 30 and an annular lubricant-different bores in the sealing cap 14 chamber 32- to enable. The lubricant chamber in connection with the risers 49, 52 and SS 32 is thus in direct fluid communication, the fluid pressure on each side is connected to the motor 10 and allows all of the ring seals 35, 36 and 37 to expand substantially Warming. same. It has been found, however, that despite

An open upper end 33 of the sealing cap 14 the fact that the liquid pressure at each is in direct communication with the outside of such an annular seal is the same when in liquid. In the sealing cap 14, a bushing 55 is fixed in the event of failure or poor functioning of the seal 34, which surrounds the shaft 18 in order to prevent the penetration of foreign bodies from entering during the rotation of the shaft 18. Takes place in the liquid through the seal. Although sealing cap 14 is a plurality of ring seals 35, the reasons for this are not entirely clear, the flux 36 and 37 are provided. Each of the ring seals 35, always in the same direction, and can perhaps be explained with the help of 36 and 37 consists of a rotating dichroic theory that the ring seal acts as a seal body 38 with a radial sealing surface 39, centrifugal pump. With particular reference to the ring seal 35 on the radial surface of a stationary seal, it has been found that the device body 40 slides. The rotating seal failure of this seal a flow from the locking body 38 of the ring seal 35 is by means of chamber 45 in the locking chamber 44 takes place. In a compressed helical spring 41, which is 65 in the same way, in the event of failure of the snap ring seal 36 attached to the shaft 18, a flow of liquid is supported by the locking ring 42, elastically against the stationary chamber 45 downward into the locking chamber 46, Sealing body 40 pressed. The ring seals 36 because the ring seal 36 is reversed to the ring seal

35 is incorporated Similarly, a liquid stream finds fluids in the motor and seal assembly;

if the ring seal 37 is caused by the locking 11 failure, only a lifting causes ur

chamber 32 up into chamber 46 instead. Lowering the separating mirror 62 in the riser £

Via a passage 60 in the intermediate wall of the bore 54 and the barrier chamber 44. It tr

body 15 is therefore no borehole fluid in the lubricant in the bottom of the lubricant

mer 32 a separating liquid with a higher chamber 32, nor can it come into contact with de

specific gravity as. the previously filled lubricant come.

Admitted lubricant. By introducing the In F i g. 6 shows an operating state in which de

Separating fluid, some of the lubricant will make the ring seal 35 fail or work poorly

upward through the riser 55 and the bore xo As previously described, the flow runs

54 is displaced into the locking chamber 44 and exits from the locking chamber 45 upwards into the lock the open upper end 33 of the sealing cap 14 chamber 44. Initially, the flows in the riser out. The selected separating liquid is opposite the "49, the bore 47, the passage 48 and the lock: Motor fluid indifferent, i.e. insoluble, and lubricant present in chamber 45 through di due to the different specific ge 15 ring seal 35 in the locking chamber 44 and ver Importantly, a separating mirror 61 is formed between which mingles with the borehole fluid. However, ver Separating fluid and the lubricant. When it comes in, this initial leakage reduces the total fill further separating liquid through the passage volume of the lubricant and the separating liquid 60, the separating mirror 61 rises in the lubricating arrangement 11 in the sealing arrangement 11. The separating mirror 6 middle chamber 32 and displaces the lubricant 20 therefore rises in the lubricant chamber 32; de up through the riser 55 until the separating separating mirror 62 falls into the bore 54 and de 61 mirror the lower open end 56 of the riser riser 55. Since the separating mirror 61 over there

55 has reached. From now on, the separating liquid will rise to the lower end 50 of the riser line 49, there will be pushed up through the riser 55, and through only separating liquid into the riser 49, ie: the amount of lubricant in the housing chamber 25 bore 47 and the passage 48 increase unc 32 remains constant. through the ring seal 35 in the direction of the arrows 6:

Separating liquid is poured in until it flows. Since the separating liquid has a larger specific

the lubricant completely from the riser 55, fish weight than the borehole fluid, collect

the bore 54 and the barrier chamber 44 displaced it melts at the bottom of the barrier chamber 44 at unc.

is. This liquid level is essentially in 30 flows through the bore 54 down into the riser

F i g. 3 shown. line 55. Continuous licking of the ring seal

A rise in temperature has the consequence that the device 35 has no loss of lubricant!

Lubricant and the separating liquid result in the sealing and separating liquid, but only one

expansion arrangement 11. This causes circulation.

Fluid upward through the riser 55 and 35 In the event of failure of the bore 54, the fluid flows into the borehole fluid according to the same principle. Until the annular seal 36 drops liquid through the riser 49, separating mirror 61 under the open end 56 of the riser, the bore 47 and the passage 48 into the blocking line 55, a lot of separating liquid is chamber 45 and then through the annular seal 37 in through the riser 55 pushed up. Thereupon the locking chamber 46. From there it flows through the lubricant can flow into the riser 55. 40 bore 51 and the riser 52 back into the. The lubricant rises back due to its smaller lubricant chamber 32. This circulating specific gravity in the form of droplets or liquid can be either separating liquid or a fine stream in the riser 55, the drilling lubricant, which from the respective position 54 to the barrier chamber 44 on. When the motor of the separating mirror 61 depends. In the same way, temperature has reached its maximum value, if the 45 failure of the ring seal 37 results in the lubricant rising up through the lubricant from the lubricant chamber 32 to the riser 55, and the separating mirror 61 is located at the top of the barrier chamber 46 and then through at the level of the open ends 50, 53 and 56. the bore 51 and the riser 52 back into the

As the fluids cool in the engine lubricant chamber 32 flows back. Failure

and the sealing arrangement again finds a 5 ° and consequently the leakage of more than one of the

Volume reduction instead. As in particular from ring seals 35, 36 and 37 did at the same time

F i g. 5 can be seen ", the only consequence of this volume is that liquid in one of the

The reduction in volume in the locking chamber 44, revolves around the enclosed directions.

Bore 54 and the riser 55 has existing In the case of the sealing arrangement described

Separating fluid back, and the borehole follows the inevitable leakage of an annular seal.

liquid. By reducing the amount of fluids, there is an overall loss of fluid in the engine and

keitsvolumens increases the separating mirror 61 in the sealing arrangement as a result, but causes

Lubricant chamber 32 on. A second separating mirror simply circulates this liquid through the

gel 62 is formed in riser 55. The leaking ring seal. It also gets itself

The volume of the riser 55 is relatively large, 60 during the leakage of an annular seal

so that when the volume of the separating lubricant is reduced, it does not come into contact with the external fluid.

Mirror 62 does not sink below the open end 56. It is therefore a harmful mixing

can. Prevented when reheating and increasing volume. Therefore, the failure of a.

If the mirror 62 in the riser seal does not appear, the failure of the seal arrangement

and the bore 54 is raised again. A hint as to the ring seal at a standstill

derholtcs switching the motor 10 on and off, the motor failed and the external fluid in the seal

which infiltrates an expansion and contraction of the fluid arrangement.

1 sheet of drawings

Claims (2)

1 2 at least as large as that due to operational conditions. Claims: temperature changes caused volunv- change of lubricant is. I. Sealing arrangement for sealing the A sealing arrangement of this type is known: Drive motor one of drive motor and 5 (U.S. Patent No. 2,783,400). The one in the Schmi Separating liquid arranged in the center chamber of the pump's existing submersible unit has c Compared to a flow surrounding the unit, temperature expansions of the lubricant Means with an above the drive such as when lowering the unit for example motor arranged, filled with lubricant in a borehole and when starting up the unit. Intercept lubricant chamber, the upper section of which io gats occur. For example, it expands The lubricant is discharged via a flow connection with the surface, so the surface is lowered drive motor is connected. with at least one level of the separating liquid in the lubricant Above the lubricant chamber arranged, chamber from, while the surface level <_ The ring seal surrounding the drive shaft, the separating liquid rises in the riser, would be: the lubricant chamber compared to the 15 separating liquid when the lubricant cools down Seals giving fluid, a rise behaves in reverse. Temperature changes d line that has the lower section of the lubricant thus only a »pendulum: middle chamber with the surrounding flow of the separating liquid result, without c medium above the ring seal connects, and sealing function of the sealing arrangement beei a separating liquid that has a greater specificity. has the same weight as the lubricant and if, however, that above the lubricant the lower portion of the lubricant chamber mer arranged ring seal will leak is at least up to the level of the mouth of the riser - inevitable that the surrounding liquid rr line and at least part of the riser comes into contact with the lubricant. At c line fills, the volume of the riser 25 known sealing arrangement is with c at least as large as the operational lubricant chamber a second lubricant chamber Volumes caused by temperature changes connected in series, which are also switched on Change of the lubricant is, g e k e η η - riser and a ring seal formed L characterized by at least one of two.This provides a certain amount of security for the company. Ring seals (35, 36) sealed locking chamber 30 that one of the ring seals will leak, provided. mer (45), which fails over at least up to the leakage of both ring seals but; The mouth plane of the first riser (55) also has this arrangement. stretching riser (49) with the lower The invention is based on the object ei; Section of the lubricant chamber (32) in a sealing arrangement for such a submersible commitment. 35 to create a unit that also d 2. Sealing arrangement according to claim 1, ring seal and temperature-dependent volume: characterized by a second, one of the other changes, a perfect seal between the Ren ring seal (37) sealed barrier chamber to the lubricant and the surrounding liquid (46), which is also guaranteed to have a minimum of up to. to the mouth plane of the two risers 40. The invention achieves this with a seal (55, 49) extending riser (52) with the arrangement of the type mentioned above through mi: seal the lower portion of the lubricant chamber (32) at least one of two ring seals communicates. Barrier chamber, which is at least up to zi Muzzle plane of the first. Extend riser c 45 riser with the lower section of the Schmie Middle chamber is in communication. If in this arrangement one of the two rings The invention relates to a sealing gasket and thus fluid ai arrangement for sealing the drive motor one of the locking chamber flows out, is through the with d. 50 barrier chamber connected riser separating liquid consisting of drive motor and pump: _ capable aggregate compared to a the aggregate speed sucked into the barrier chamber. The separating liquid surrounding fluid with a speed above then flows either directly or via d. Drive motor arranged, other riser with lubricant (depending on which of the two filled the lubricant chamber, the upper section of which has leaked ring seals) into the forge 55 back via a flow connection with the drive center chamber. This creates a circ motor is connected, with at least one above lation of the separating fluid, without a lubrication groove: arranged in the lubricant chamber, the liquid on or around it has become through the leak Ring seal surrounding the drive shaft, which leaks through the ring seal. Lubricant chamber compared to the surrounding based on the drawings is in an Au. Seals fluid, a riser that brings the essence of the invention to the 60 management example: the lower section of the lubricant chamber with the explained. It shows surrounding fluid above the ring- Fig. 1 is a longitudinal section through a with a: seal connects, and a separating fluid, the aggregate provided borehole, a greater specific weight than the lubricating Fig. 2a, 2b each a section in enlarged medium and the lower portion of the grease scale along the line 2-2 in FIG. 1, where F i g. Z middle chamber at least up to the mouth level the upper and Fig. 2b the lower half of the A. of the riser and at least part of the order, riser fills, the volume of the riser Fig. 3 to 6 in a schematic representation longitudinal