DE19706371A1 - Electric generator for current generation in bore trace - Google Patents

Abstract

The electric generator is adapted to be built into a bore trace for sinking a deep bore and is driven by a digging wheel. The generator has a stator (5) with a winding and a rotor (12) with permanent magnets. The stator (5) has a cylindrical tubular iron core (7) surrounded by a winding (8). A cylindrical cladding sleeve (10) of non-magnetic material is provided around the winding (8) and the core (7). The rotor (12) is rotatably mounted on the stator (5) and is formed as a hollow cylinder around the cladding sleeve (10) of the stator (5). The rotor (12) has an iron sleeve (14) and diametrically arranged permanent magnets (16,17). The permanent magnets (16,17) generate a magnetic field which cuts across the stator winding (8) and rotates with the rotor (12). A digger collar (20) is fastened to the rotor. This is rotated by the coil current during drilling.

Description

The invention relates to an electrical generator, which in a drill string can be installed to sink a deep borehole and through a show that can be filled with drilling fluid Felwheel is drivable.

When sinking deep wells are usually in the Drill string built-in borehole meters used During drilling, information about the drilling direction and the Provide drilling conditions in the borehole. The measurement data obtained are here from a telemetry device, for example wise with the help of pressure generated in the drilling fluid pulse, transmitted to surface. To the measuring devices and the To supply telemetry device with electrical energy gen, next to batteries are installed in the drill string Generators used with the help of a paddle wheel by the flow of the drilling fluid directed towards the drill bit are driven. The main problem here is the driving force from the impeller to the rotor of the in a pressure-tight housing encapsulated electrical Generator to transmit without the tightness of the housing to affect.

From DE 34 39 802 A1 it is known the electrical Borehole signal transmitter generator for transmission of measurement data to the earth's surface through a magnetic coupling  with a paddle wheel to drive the generator to kup peln. The generator is filled with hydraulic oil Housing arranged, one in the wall of the housing flexible membrane is provided, which is a hydrostatic Balance between the interior of the housing and the environment of the housing. The magnetic coupling consists of a shaft connected to the rotor of the generator, the is rotatably mounted within the housing and permanent magnets that are even around the circumference of the shaft are widely distributed. On the outside of the case is a Drive ring made of copper rotatably mounted with a Paddle wheel is firmly connected. If the paddle wheel rotates in the flow of the drilling fluid in the copper drive ring through the field of permanent magnets eddy currents induced, which creates a braking torque that the rotation force of the paddle wheel on the shaft of the magnetic coupling transmits. This known configuration of the generator drive is comparatively complex. She still has that Disadvantage that the rotational movement of the clutch shaft and Generator rotor filled with oil for pressure compensation housing requires a considerable amount of energy to survive requires fluid friction.

The invention has for its object one in one Drill string to create usable electrical generator which is characterized by a low construction cost, an inexpensive Efficiency and a small space requirement net.

This object is achieved in that the Stator of the generator out as a cylindrical tube formed iron core, a winding surrounding the iron core and envelop the winding and the iron core in a pressure-tight manner lumbar, cylindrical sleeve made of a non-magnetic Has material and that rotatably on the stator gerte rotor is designed as a hollow cylinder, the Man  surrounds the stator and a sleeve made of iron and in this in a diametrical arrangement permanent magnets having a crossing the winding of the stator with generate the rotating magnetic field, at which Rotor is attached to a blade ring which is used during drilling can be driven to rotate by the flushing flow.

The generator according to the invention uses a magnetic field as it does in the known magnetic coupling for the transmission of Driving torque is required immediately to get in a voltage to the standing copper winding of the stator induce, the pressure-tight encapsulation of the sensitive Chen electrical parts of the generator through the in the Gap sleeve is equally given. The design of the generator according to the invention draws in addition to the elimination of the construction work for the known Magnetic coupling through a number of surprising advantages out. This shows that the arrangement of the magnets in a stronger magnetic field enables the external rotor light is as with a typical for bell anchor runners Central arrangement of the magnets. Because of this stronger Magnetic field are caused by the jacket sleeve Gap losses largely compensated, so that the effect degree of the generator that of a generator with rotating Bell anchor between the inner magnet and an outer iron housing is comparable. This also contributes at that magnetic gap loss between the iron core of the stator and the ironless copper winding. There the pressure-tight housing does not ent any rotating components holds, it can also fill the housing with oil Pressure compensation does not lead to friction losses. There on the other hand, no large volume inside the housing Cavity for the rotating parts of a magnetic coupling and the rotor of the generator is needed, the housing also be designed so that they are pressure-resistant to an oil filling can be dispensed with for pressure compensation. The firmest  iron core in the center of the generator allowed towards an electrical continuity without a transformer, whereby an unrestricted positioning of the generator in son the similar borehole meters is made possible.

Another structural advantage is given by the fact that tubular iron core, the winding and the casing sleeve by sheathing the winding spaces with an iso form a pressure-resistant solid body can, which supports the jacket sleeve, so that it is very thin can be dimensioned to the magnetic gap width small and thus keep the magnetic losses low. The gap-free coupling of the ironless winding to the Iron core and the casing sleeve, which can be indirect contact with the drilling fluid is cooled, enables extremely low thermal resistance, compared to a conventional, air-running Generator armature is <5%. This results in the greatest possible Use of the permissible maximum winding temperature from to to 200 ° C in the winding arrangement supported according to the invention nung. The temperature gradient can be compared to reduce an air-running anchor to 1/10. The The inventive design of the generator therefore allows high speeds and a specific power density of <1 VA / ml construction volume under operating conditions in the borehole. It follows that under in situ temperatures of 140 ° C higher power densities than with a conventional genera can be reached under normal operating conditions.

The favorable efficiency and the admissibility of high rotation numbers still allow low drive torque, whereby the drive-related abrasions are low, because the pitch angle of the blades can be chosen to be small. Also guide vanes to improve the flow of the show In view of the low requirements, bicycles are unnecessary chen drive torque.  

An embodiment of the invention is particularly advantageous generator according to the invention, in which the rotor has an inner Bearing sleeve made of non-magnetic material and the Jacket sleeve of the stator and the bearing sleeve together Form a plain bearing to support the rotor. The plain bearing can here by the drive medium, for example the Drilling fluid, be lubricated so that special Sealing measures are not necessary. Because of the cheap dimensions solutions, the plain bearing has a long service life and enables light long service life. It can also be provided be that the jacket sleeve and / or the bearing sleeve from one ceramic material. Such material is eddy current free and very low wear.

For axial mounting, the rotor of the generator can be attached to one Axial plain bearing made of hard metal or ceramic Have material, the other end of the rotor Rotor and the stator repelling ring-shaped per Wear magnet magnets that free the thrust slide bearing hold. This ensures that the rotor is reversed drilling mud only on the ver with a permanent magnet seen end of the rotor over an annular gap between the Stator and the rotor in the bearing gap of the plain bearing arrive, but not continuously in the longitudinal direction can flow through. In this way the entry of Dirt particles prevented in the slide bearing. In addition can do this a labyrinthine design of the annular gap contribute.

The buckets of the bucket crane arranged on the rotor According to the invention, zes can be made from an elastomeric material consist. It has been shown that such a material at approaching speeds of 30 m / s downtime achieved by hard metal and a gap-free dimensioning the radial blade length enables. Preferably have  the blades have a T-profile and are with the crossbars of the T-profile in a suitably shaped, curved pro interchangeable filnut in the lateral surface of the rotor The manufacture of the blades can be done easily by separating from each forming a blade Sections are made from a longer profile band.

The winding of the generator can be made according to a suggestion Invention of three or a multiple of three in the same Chen circumferential distance from each other Coil strands consist of a triangle or polygon are switched and tapped at the connection places of the coil strands. Such a triangular or polygonal circuit offers ideal conditions for a commutatorless diode rectification with little rest ripple that requires little smoothing. Undesired spark interference does not occur.

The invention is illustrated below with the aid of an embodiment game explained in more detail, which is shown in the drawing is. Show it

Fig. 1 shows a longitudinal section through a built in a measuring probe for use in a drill string and generator

FIG. 2 shows a cross section through the generator according to FIG. 1.

The generator shown in the drawing is arranged in a housing 1 , which consists of a cylindrical tube 2 and nipples 3 , 4 screwed into the ends of the tube 2 . The housing 1 is part of a measuring probe which can be used to carry out measurements when drilling into a drill string.

The generator has a central stator 5 in the form of a cylindrical rod, which is held in a rotationally fixed manner in receiving bores in the facing end faces of the nipples 3 , 4 and is sealed by sealing rings 6 . The stator 5 consists of an iron core 7 , which is designed as a cylindrical tube and consists of an eddy current-inhibiting mate rial, for example sheet metal fins. On the iron core 7 , a winding 8 is arranged, which is shaped like a bell armature and has three 120 ° staggered, connected in a triangle coil strands. From the junctions of the coil strands lead lines 9 through radial bores and the longitudinal bore in the iron core 7 to rectifiers, not shown. The iron core 7 and the winding 8 are surrounded by a cylindrical, thin-walled jacket sleeve 10 , which consists of a non-magnetic, non-conductive and wear-resistant material, in particular a ceramic material. The winding 8 receiving the annular space between the iron core 7 and the jacket sleeve 10 is poured ver with a synthetic resin material and sen to the outside with an intermediate sleeve 11 . In this way, a pressure-resistant solid body is formed, which supports the casing sleeve 10 , so that it can have a very small wall thickness.

On the stator 5 , a rotor 12 is rotatably mounted, which has an inner bearing sleeve 13 , an outer sleeve 14 and in an annular space 15 provided between the two sleeves 13 , 14 twice four opposite rows of permanent magnets 16 , 17 . The bearing sleeve 13 is made of a non-magnetic material and the sleeve 14 is made of iron. The permanent magnets 16 are aligned with their south pole, the permanent magnets 17 with their north pole towards the stator 5 . The remaining cavities in the annular space 15 are potted with a synthetic resin and the annular space 15 is closed at the end faces by spacer rings 18 . The described parts of the rotor 12 are arranged for their protection in a sleeve 19 made of hard metal, which carries in the middle a plurality of blades 20 arranged uniformly distributed over the circumference. The outer surface of the sleeve 19 is flared towards the ends in order to achieve a favorable flow against the blades 20 by the drive medium, which is supplied and discharged through slots 21 , 22 in the tube 2 . The blades 20 consist of a rigid elastomer and have a T-shaped cross section, the crossbar of which forms the blade root 21 , which is held in a longitudinally curved groove in the sleeve 19 . The use of elastomeric blades prevents breakage or blocking due to any hard foreign bodies.

To mount the rotor 12 on the stator 5 , the man telhülse 10 and the bearing sleeve 13 form a slide bearing 22 which is lubricated by the drive medium, namely the drilling fluid. In the bearing gap of the plain bearing 22 , the drive medium passes through an annular gap 23 which is bent down several times and which is provided on the end of the rotor 12 facing the nipple 3 . The annular gap 23 is held open by two repelling, annular permanent magnets 24 , one of which is attached to the nipple 3 and one to the rotor 12 . At the other end of the rotor 12 , an axial sliding bearing 25 is provided, which is formed by the end face of the sleeve 19 facing the nipple 4 and a hard metal bearing ring 26 screwed onto the nipple 4 . Since the sliding surfaces of the axial slide bearing 25 are kept in constant contact by the permanent magnets 24 , the axial slide bearing 25 forms a sealing point between the bearing gap of the slide bearing 22 and the flow channel on the outside of the rotor 12 . The bearing gap of the plain bearing 22 is therefore only connected to the flow channel via the annular gap 23 and is therefore not flushed through in the longitudinal direction. As a result, the entry of abrasive dirt particles is largely avoided.

As the described embodiment shows, enables the generator design according to the invention a very compact and short design with one for drilling Hole applications, especially in draggable navigation systems stemen, desirable small diameter. The high we efficiency of the generator enables low drive torques and therefore also a small impeller diameter. The large-dimensioned plain bearings are low-wear and result in long service life and the fixed iron core in the center of the generator allows free passage electrical lines, so that the generator at each anywhere in a chain connected to a probe which downhole meters can be arranged.

Claims (10)

1. Electrical generator which can be installed in a drill string for sinking a deep borehole and can be driven by a paddle wheel which can be charged with the drilling fluid and which has a stator provided with a winding and a rotor provided with permanent magnets, characterized in that the stator ( 5 ) an iron core ( 7 ) formed as a cylindrical tube, a winding ( 8 ) surrounding the iron core ( 7 ) and a cylindrical jacket sleeve ( 10 ) which encloses the winding ( 8 ) and the iron core ( 7 ) in a pressure-tight manner and is made of a non-magnetic material and that on the stator ( 5 ) rotatably mounted rotor ( 12 ) is designed as a hollow cylinder which surrounds the jacket sleeve ( 10 ) of the gate ( 5 ) and which has a sleeve ( 14 ) made of iron and in this in a diametrical arrangement permanent magnets ( 16 , 17 ), which generate a winding ( 8 ) of the stator ( 5 ) crossing, with the rotor ( 12 ) rotating magnetic field, on the rotor ( 12 ) egg n rocking ring ( 20 ) is fastened, which can be driven in rotation by the mud flow during drilling. 2. Generator according to claim 1, characterized in that the tubular iron core ( 7 ), the winding ( 8 ) and the jacket sleeve ( 10 ) form a pressure-resistant mas sivkörper by casting the spaces with an insulating plastic. 3. Generator according to one of claims 1 or 2, characterized in that the rotor ( 12 ) has an inner bearing sleeve ( 13 ) made of non-magnetic material and that the casing sleeve ( 10 ) of the stator ( 5 ) and the bearing sleeve ( 13 ) with each other form a slide bearing ( 22 ) for mounting the rotor ( 12 ). 4. Generator according to one of the preceding claims, characterized in that the sliding bearing ( 22 ) is lubricated by the drive medium, for example the drilling fluid. 5. Generator according to one of the preceding claims, characterized in that the jacket sleeve ( 10 ) and / or the bearing sleeve ( 13 ) consist of a ceramic material. 6. Generator according to one of the preceding claims, characterized in that the rotor ( 12 ) at one end has an axial sliding bearing ( 25 ) made of hard metal or ceramic material and that at the other end of the rotor ( 12 ) the rotor ( 12 ) and the stator ( 5 ) carries repelling, ring-shaped permanent magnets ( 24 ) which keep the axial sliding bearing ( 25 ) free of play. 7. Generator according to one of the preceding claims, characterized in that the blades ( 20 ) of the blade ring arranged on the rotor ( 12 ) consist of an elastomeric material. 8. Generator according to one of the preceding claims, characterized in that the blades ( 20 ) have a T-profile and are held interchangeably with the crossbars of the T-profile in a correspondingly shaped, curved profile groove in the lateral surface of the rotor ( 12 ). 9. Generator according to one of the preceding claims, characterized in that the blades ( 20 ) are made by separating sections forming a blade th from a longer profile strip. 10. Generator according to one of the preceding claims, characterized in that the winding ( 8 ) consists of three 120 ° C staggered coils, which are connected in a triangle and have taps at the three connection points of the coil strands.