DE102023100549A1 - A dynamic grinding device for slip ring in large-scale paddle wheel type axial flow water turbogenerator - Google Patents

Abstract

This invention provides a dynamic grinding device for slip ring in the large scale axial flow paddle wheel type water turbo generator, comprising a base, the base having a parallel slider with a column thereon, the column being provided with a lifting mechanism, the lifting mechanism having a Lifting block is connected, which is provided with a tool holder at the front end, wherein the parallel slider is connected to a parallel drive mechanism provided on the base, the lifting mechanism is connected to a driving machine, so that the tool holder by means of the cooperation of the parallel drive mechanism and lifting mechanism moves or advances up and down or back and forth to carry out on-site repair of the non-removable slip ring. This device can grind the friction surface of the slip ring rough, fine and fine when the generator is idling to improve the work efficiency, shorten the maintenance time and ensure the safe or stable operation of the generator for a long period of time.

Description

Technical area

The present invention relates to an online repair and grinding device for the friction surface of the slip ring of a generator, particularly to a dynamic grinding device for slip ring in the large-scale axial flow paddle wheel type water turbogenerator, which belongs to the field of mechanical design and manufacturing technology.

Background technology

The task of the slip ring of a generator is to introduce the excitation current into the pole coil or to introduce the current from the stationary carbon brushes into the rotating rotor winding by frictional contact between the carbon brushes and the outer circular surface of the slip ring while maintaining a certain pressure. The slip ring produces different levels of removal and wear with the carbon brush during use. If wear goes beyond the tolerance range, the friction surface of the slip ring must be replaced, otherwise the functional quality of the carbon brushes and the slip ring will be impaired. For generator sets of the mixed current, Stol type, etc., the slip ring can be removed and then sent back to the manufacturer for calibration and repair. In large axial flow paddle wheel type generators, the upper end of the slip ring is equipped with the oil collector, power hydraulic system and copper plates, so both disassembly and reassembly are difficult, and the disassembly and assembly process is complicated, time-consuming and inefficient. There is therefore a need for a state-of-the-art innovation.

Content of the invention

In order to solve the problem that it is difficult to disassemble and reassemble the slip ring of a large-scale axial flow paddle wheel type water turbogenerator, resulting in inconvenience in repairing and grinding the slip ring, the present invention provides a dynamic slip ring grinding apparatus in a large-scale water turbo generator of the paddle wheel type with axial flow.

The present invention is completed by the following technical solution: A dynamic grinding device for slip ring in large-scale axial flow paddle wheel type water turbogenerator, comprising a base, the base having a parallel displaceable slide with a column thereon, the column being provided with a lifting mechanism is, wherein the lifting mechanism is connected to a lifting block provided with a tool holder at the front end, the parallel sliding slider being connected to a parallel driving mechanism provided on the base, the lifting mechanism being connected to a driving machine, so that the Tool holder moves or advances up and down or forward and backward by means of the interaction of the parallel sliding drive mechanism and lifting mechanism to carry out online repair and on-site grinding of the non-removable slip ring, improving the work efficiency but also shortening the maintenance time to ensure the normal operation of the generator.

The top of the base is provided with a long dovetail-shaped projection, the two sides of which are inclined from the outside inwards, the long dovetail-shaped projection being arranged horizontally on the top of the base and its length being adapted to the length of the base, the parallel movable slider is disposed on the top of the base and is slidably connected to the long dovetail-shaped projection on the top of the base by means of a dovetail slide disposed on the floor; wherein a horizontal slide with the opening upward is provided along the top of the long dovetail-shaped projection, the horizontal slide being slidably connected to a movable block located at the bottom of the dovetail-shaped slide so that the parallel-slidable slider slides along the long dovetail-shaped projection slides back and forth, which further improves the stability of the back and forth sliding by sliding the movable block along the horizontal slide, while the parallel sliding slider can slide easily.

The parallel sliding drive mechanism includes an axial screw hole disposed along the movable block at the bottom of the dovetail slide, a horizontal spindle being screwed to this axial screw hole, the two ends of this horizontal spindle each being rotatably connected to the mounted bearing mounted on the corresponding end of the top of the base, with the outer end of the horizontal spindle extending outward and connected to a handwheel so that the handwheel can drive the horizontal spindle to rotate and then the movable block and the parallel to drive the sliding slider back and forth along the horizontal spindle.

The column is arranged vertically on the top of the parallel sliding slider, the column being provided with a vertical dovetail-shaped slot, the opening of which is oriented outwards, the vertical dovetail-shaped slot being provided with a vertical spindle inside, the vertical spindle with is screwed to a lifting block, the front end of the lifting block being provided with a tool holder, with dovetail-shaped projections each being arranged on both sides of the lifting block, each of which fits vertical dovetail-shaped slots, the lifting block being provided with a rectangular block in the middle, wherein the rectangular block is provided with a vertical screw hole for screwing to the vertical spindle so that the rotating vertical spindle drives the lifting block in up and down movements along the vertical spindle.

The lifting mechanism includes a vertical spindle disposed in the vertical dovetail slot of the column, the upper and lower ends of the vertical spindle being rotatably connected to the mounted bearings disposed in the upper and lower portions of the vertical dovetail slot, wherein the upper end of the vertical spindle extends upward and is connected to the turbine and the turbine is arranged with the screw at the top of the column, both ends of the screw being connected to the mounted bearings at the top of the column, one end of the Worm is connected to the output shaft of the gearbox at the top of the column, with the input shaft of the gearbox connected to the main shaft of the prime mover, so that the turbine and the worm are rotated by the prime mover, which in turn drives the vertical spindle in rotation.

The tool holder has a conventional design so that the tool holder can be used to hold repair tools such as turning tools and grinding wheels.

The present invention has the following advantages and effects: Using the above solution, in the idle state of a large-scale axial flow paddle wheel type water turbogenerator, it is not necessary to remove the upper end of the slip ring, the oil collector, the power hydraulic system and the copper plate and other large To disassemble assemblies, the tool holder moves or advances easily up and down or back and forth by means of the cooperation of the parallel sliding drive mechanism and lifting mechanism to carry out online repair and on-site grinding of the non-removable slip ring, improving work efficiency , but also to shorten the maintenance time to ensure the repair of the generator, the grinding quality and the smooth operation of the generator. So it is actually an ideal sander.

Illustration of the accompanying drawings

• 1 shows a main view of the invention;
• 2 shows a side view of the invention;
• 3 shows a top view of the invention.

Specific Embodiments

The present invention is described in more detail below in conjunction with the accompanying drawings.

The present invention provides a dynamic grinding device for slip ring in the large scale axial flow paddle wheel type water turbo generator, comprising a base 1, the base 1 having a parallel displaceable slide 11 with a column 9 thereon, the column 9 being provided with a lifting mechanism 4 is, wherein the lifting mechanism 4 is connected to a lifting block 10 which is provided with a tool holder 8 at the front end, the parallel displaceable slider 11 is connected to a parallel displaceable drive mechanism 15 which is provided on the base 1, the lifting mechanism 6 being connected to a Drive machine 5 is connected so that the tool holder 8 moves or advances up and down or forwards and backwards by means of the interaction of the parallel displaceable drive mechanism 15 and lifting mechanism 4 in order to carry out online repair and grinding of the non-removable slip ring 23 on site , improve work efficiency, but also shorten maintenance time to ensure the normal operation of the generator.

The top of the base 1 is provided with a long dovetail-shaped projection 12, the two sides of which are inclined from the outside inwards, the long dovetail-shaped projection 12 being arranged horizontally on the top of the base 1 and its length adapted to the length of the base 1 is, wherein the parallel displaceable slide 11 is arranged on the top of the base 1 and by means of a dovetail-shaped slide 18 arranged on the floor with the long dovetail-shaped projection 12 on the top the base 1 is slidably connected; wherein a horizontal slide 16 with the opening upward is provided along the top of the long dovetail-shaped projection 12, the horizontal slide 16 being slidably connected to a movable block 17 located at the bottom of the dovetail-shaped slide 18, so that the parallel sliding slider 11 slides back and forth along the long dovetail-shaped projection 12, which further improves the stability of the reciprocating sliding by sliding the movable block 17 along the horizontal slide 16, while the parallel sliding slider 11 can slide easily.

The parallel sliding drive mechanism 15 includes an axial screw hole disposed along the movable block 17 at the bottom of the dovetail-shaped slide 18, a horizontal spindle 13 being screwed to this axial screw hole, the two ends of this horizontal spindle 13 each being rotatable with the mounted bearing are connected, which is arranged at the corresponding end of the top of the base 1, with the outer end of the horizontal spindle 13 extending outwards and connected to a handwheel 14 so that the handwheel 14 can drive the horizontal spindle 13 to rotate and then drive the movable block 17 and the parallel slider 11 back and forth along the horizontal spindle 13.

The column 9 is arranged vertically on the top of the parallel displaceable slide 11, the column 9 being provided with a vertical dovetail-shaped slot 7, the opening of which is oriented outwards, the vertical dovetail-shaped slot 7 being provided with a vertical spindle 6 inside , wherein the vertical spindle 6 is screwed to a lifting block 10, the front end of the lifting block 10 being provided with a tool holder 8, with dovetail-shaped projections 20 being arranged on both sides of the lifting block 10, each of which fits into vertical dovetail-shaped slots 7, wherein the lifting block 10 is provided with a rectangular block in the middle, the rectangular block being provided with a vertical screw hole 19 for screwing with the vertical spindle 6 so that the rotating vertical spindle 6 moves the lifting block 10 along the vertical spindle 6 drifts up and down.

The lifting mechanism 4 includes a vertical spindle 6 disposed in the vertical dovetail slot 7 of the column 9, the upper and lower ends of the vertical spindle 6 being rotatably connected to the mounted bearings 2 located in the upper and lower parts of the vertical dovetail Slot 7 are arranged, with the upper end of the vertical spindle 6 extending upwards and connected to the turbine 3 and the turbine 3 with the screw 22 is arranged at the top of the column 9, with both ends of the screw 22 with the mounted Bearings 23 are connected to the upper end of the column 9, one end of the worm 22 being connected to the output shaft of the gearbox 21 at the upper end of the column 9, the input shaft of the gearbox 21 being connected to the main shaft of the prime mover 5, so that the Turbine 3 and the screw 22 are rotated by the drive machine 5, which in turn drives the vertical spindle 6 in rotation.

The tool holder 8 is constructed conventionally, so that the tool holder 8 can be used to hold repair tools such as turning tools and grinding wheels.

Claims (5)

A dynamic grinding device for slip ring in large scale axial flow paddle wheel type water turbo generator comprising a base, characterized in that the base has a parallel displaceable slider with a column thereon, the column being provided with a lifting mechanism, the lifting mechanism with a lifting block is connected, which is provided with a tool holder at the front end, the parallel displaceable slider being connected to a parallel displaceable drive mechanism provided on the base, the lifting mechanism being connected to a driving machine. A dynamic grinding device for slip ring in large scale water turbo generator of paddle wheel type with axial flow Claim 1 , characterized in that the top of the base is provided with a long dovetail-shaped projection, the two sides of which are inclined from the outside inwards, the long dovetail-shaped projection being arranged horizontally on the top of the base and its length adjusted to the length of the base is, wherein the parallel slider is arranged on the top of the base and is slidably connected to the long dovetail-shaped projection on the top of the base by means of a dovetail-shaped slide arranged on the floor; wherein a horizontal slide with the opening upwards is provided along the top of the long dovetail-shaped projection, the horizontal slide having a movable is slidably connected to a block located at the bottom of the dovetail slide. A dynamic grinding device for slip ring in large scale water turbo generator of paddle wheel type with axial flow Claim 1 , characterized in that the parallel sliding drive mechanism includes an axial screw hole arranged along the movable block at the bottom of the dovetail-shaped slide, a horizontal spindle being screwed to this axial screw hole, the two ends of this horizontal spindle each being rotatable with the mounted bearing which is arranged at the corresponding end of the top of the base, with the outer end of the horizontal spindle extending outwards and connected to a handwheel. A dynamic grinding device for slip ring in large scale water turbo generator of paddle wheel type with axial flow Claim 1 , characterized in that the column is arranged vertically on the top of the parallel sliding slider, the column being provided with a vertical dovetail-shaped slot, the opening of which is oriented outwards, the vertical dovetail-shaped slot being provided with a vertical spindle inside, wherein the vertical spindle is screwed to a lifting block, the front end of the lifting block is provided with a tool holder, wherein dovetail-shaped projections are arranged on both sides of the lifting block, each of which fits vertical dovetail-shaped slots, the lifting block having a rectangular block in the center, the rectangular block being provided with a vertical screw hole for screwing to the vertical spindle. A dynamic grinding device for slip ring in large scale water turbo generator of paddle wheel type with axial flow Claim 1 , characterized in that the lifting mechanism comprises a vertical spindle disposed in the vertical dovetail slot of the column, the upper and lower ends of the vertical spindle being rotatably connected to the mounted bearings located in the upper and lower parts of the vertical dovetail slot are arranged, with the upper end of the vertical spindle extending upwardly and connected to the turbine and the turbine with the screw being arranged at the top of the column, with both ends of the screw being connected to the mounted bearings at the top of the column , wherein one end of the worm is connected to the output shaft of the gearbox at the top of the column, with the input shaft of the gearbox connected to the main shaft of the prime mover.

Images