SE505171C2 - Valve slide in a hydraulic percussion - Google Patents

Abstract

A hydraulic impact motor in the form of a water-driven in-hole rock drilling machine has a valve spool (40) that has two equally big and opposite directed control surfaces (A1 and A2). The valve has also a third control surface (A3) which is smaller than the other two and which is continuously under pressure. The third control surface (A3) acts in the same direction as the second control surface (A2). When the first control surface (A1) is under pressure but the second control surface (A2) is not, then the valve is moved in one direction, and when the first and second control surfaces (A1 and A2) is under equal pressure (full pressure or no pressure), then the valve is moved in the other direction by the third control surface (A3).

Description

505 in the housing housing 20 with a back piece 38 abutting against the spacer sleeve 19 and a tubular filter support 21 with a filter 21a abutting the back piece 38 of the slide housing 20. An end piece 22 is screwed into the rear part of the tube 12 and arranged to axially clamp the parts 18, 19, 20,38,21 against the shoulder 13. The parts 18,19,20,38,2l function together as a spring and their total length is adapted so that they are elastically compressed, preferably 0.4 - 2 mm when screwed together.

The spacer sleeve 19, due to its length and small cross-section, provides the dominant part of this spring action. It is adapted to be compressed at least 0.3 and preferably 0.8 ~ 3 per mille of its length. The filter support 21 can have approximately the same cross-section as the spacer sleeve 19, less addition to the spring action. The back piece 38 of the valve housing but it is shorter and therefore provides clamping against the main part of the valve housing 20. The end piece 22 is arranged to be screwed onto a conventional drilling pipe which transmits rotation to the drilling machine and also supplies hydraulic drive medium in the form of pressurized water to the drilling machine. The space 58 behind the slide housing 20 is thus constantly pressurized with filtered pressurized water during operation.

When mounting the machine, all parts 18,19, 20, 38, 21 are stacked loosely on top of each other, which makes mounting easy and reduces the requirements for length tolerances.

All parts slide easily in the machine housing and are therefore easy to remove during disassembly.

The tolerances are taken up by the axial compression.

A tube 23 forms part of the slide housing 20. the continuous channel 25 has its front end guided in an impact piston 24 with a guide bushing 18. The rear end of the impact piston forms a neck 27 extending into the annular cylinder space 26 formed between the sleeve-like front end 35 of the slide housing 20. and the tube 23 of the slide housing 23. The rear end of the percussion piston (neck 27) is thus controlled by the walls of the cylinder space 26. 28 with a rear edge 29 so that the percussion piston has a defined The neck 27 of the percussion piston has a sparse outer guide surface 30 behind the edge 29. Towards the tube 23 the percussion piston is ground so that it also has a sliding surface 31 of defined UJ 505 171 length, suitably with approx. the same length as the sliding surface 30.

The strut lengths 18 and 30,31 of the percussion piston occupy only a small part of the length of the percussion piston and the largest part of the percussion piston is located between the guides and has a large play against the housing sleeve 19. The piston may suitably have a thickening 32 over most of its length. get larger mass.

At the front end of the piston, the steering length is thus defined by the guide bushing 18, while the sliding surfaces 30,31 of the striking piston define the steering length at the rear end of the striking piston.

The styrene lengths together occupy less than 20% of the length of the percussion piston.

The guide surface 33 of the piston against the guide bush 18 has a smaller diameter than the guide surface 30 against the slide housing so that the percussion piston has a differential piston surface in the front cylinder space 34 formed between the guide bush 18 and the slide housing 20. This differential piston surface can be considered part of the surface designated 36. This differential piston surface is smaller than the annular piston surface 37 of the percussion piston in the rear cylinder space 26.

The valve housing contains a tubular valve slide 40 with three guide surfaces A1, A2 and A3 which are located in three annular guide chambers 45, 46 and 47. The surface A3 is a differential surface which arises in that the diameter of the slide surface of the slide 40 closest to A1 is larger than the diameter of the slide surface. closest to A2.

For these control surfaces the relationship A3 <A1 <A2 + A3 applies. The surface A2 is larger than the surface A3 and suitably A1 and A2 can be approximately equal in size and approximately twice as large as A3. There is a further annular chamber 48 which in the valve position shown is open towards the annular chamber 47 but in the second position of the slide is separated from the annular chamber 47 by a shoulder 49 in the valve housing. The slide 40 has a series of coarse bores 50 and two narrow bores 51. A guide channel 52 leads joints between the annular chamber 46 and the rear cylinder space 26 with a guide port 53 to the cylinder space 26.

Another guide channel 54 leads between the annular chamber 45 and the rear cylinder space 26 with guide ports 55 and 56 to the cylinder spaces 26 and 34. A number of parallel channels 57 lead axially straight through the valve housing 20 and connect the front cylinder space 34 to the constantly pressurized space 58 behind the slide housing 20. A number of channels 59 connect a series of ports 60 in the rear cylinder space 26 to a series of ports 61 in the annular chamber 48. A number of channels connect a series of ports 62 in the annular chamber 47 to the constantly pressurized space 58 behind the slide housing 20. .

Assume that the slide 40 is in its position shown and that the percussion piston 24 has started its working stroke to strike the drill bit 14. (The percussion piston is shown in the figures in its stroke position.) The slide 40 then pressurizes the rear cylinder space 26 from the space 58 via the ports 62,61 and 60. The guide surface A1 is pressurized throughout the operation because the guide port 56 of the guide channel 54 is first open to the constantly pressurized front pressure chamber 34 and then, shortly after this guide port 56 is closed, the guide port 55 of the guide channel 54 is opened to the rear pressurized cylinder space 26.

The length of the guide surface 30 of the percussion piston can, as shown, be adjusted so that both ports 56 and 55 are closed for a short intermediate period, which, however, does not have time to affect the pressure in the guide channel 54. As long as the guide channel 52 guide port 53 is closed, the slide 40 is stable in its shown front position due to the surface A1 overcoming the surface A3.

The leakage from the annular chamber 46 prevents pressure build-up in the annular chamber 46.

When the percussion piston in its working stroke opens the control port 53 of the control channel 52 shortly after it has opened the control port 55 of the control channel 54 C '.J 505 171, the channel 52 and the annular chamber 46 are pressurized and since the surface A2 then pressurized is equal to the already pressurized surface these surfaces each other, so that the surface A3 reverses the slide to its rear position not shown. The tail 51 in the slide then comes in the middle of the annular chamber 46 mn they are so small that despite the flow through them they do not prevent the pressurization of the annular chamber 46. This loss leakage through the heel 51 is so small that it does not appreciably affect the overall efficiency. The slide 40 is damped by its nose 65 which shuts off a damping chamber so that the slide is bridged before it lands in its rear position not shown and therefore does not tend to bounce. The annular chamber 48 is shut off from the annular chamber 47 and is instead connected via the bores 50 of the slide to the interior of the slide which via the tube 12 is constantly open to the percussion channel 25 which in turn is constantly open to the flushing channel of the drill bit. The rear cylinder space 26 is therefore depressurized at the same time as the percussion piston when its stroke position and the differential piston surface of the percussion piston in the constantly pressurized front cylinder space 34 begin to drive the piston baked in its return stroke.

The mutual axial position of the guide ports 53 and 55 can be varied and the guide port 53 need not lie axially in front of the port 55.

The water flowing out of the rear cylinder space 26 during the return stroke of the percussion piston is thus used as a flushing medium to flush the drill cuttings out of the borehole.

When the rear cylinder space 26 is depressurized, both the control surface A1 and the control surface A2 are depressurized because both the port 55 of the control channel 54 and the port 53 of the control channel 52 are open towards the rear cylinder space 26.

During its return stroke, the percussion piston 24 will close the ports 55 and 53. However, the annular chamber 46 continues to be drained, now through the small bores 51 through the slide. Then the percussion piston 24 opens the port 56 of the guide channel 54 so that the guide channel 54 and the annular chamber 45 are pressurized from the front cylinder space 34 and the surface A1 is pressurized.

Since the surface A2 is not pressurized, the surface A1 slides the slide 40 to its front position in which it is shown in the figure.

During the last part of the forward movement of the slide, the two small halls 51 of the slide are shut off from the annular chamber 46 and the trapped water in the annular chamber 46 and the control channel 53 dampens the movement of the valve before the valve lands as a pressure builds up against the guide surface A2. However, because the row of large bores 50 through the slide is so close to the annular chamber 46, a pressure cannot be built up which endangers the slide remaining stable in its front position. Namely, the leakage out through the heel 50 together with the leakage over the end of the slide is greater than the leakage in through the closed port 53.

The slide now pressurizes the rear cylinder space 26 via the ports 62, 61 and 60 and the channels 59 between the ports 61 and 60 so that the percussion piston 24 is braked, turns and makes its working stroke as already described.

Claims (4)

505,171 Patent claims Hydraulic percussion device with a percussion piston (24) reciprocating in a housing and driven by the pressure 1 into two drive chambers (26, 34), at least one of which is alternately pressurized and relieved by a valve slide (40), the valve slide (40) has a first guide surface (A1) located in a first guide chamber (45) and a second guide surface (A2) located in a second guide chamber (46) and opposite said first guide surface (A1), and the first and second guide chambers are arranged to be pressurized and pressure relieved 1 depending on the position of the percussion piston via guide ports (53.55.56) controlled by the percussion piston and guide channels (52,54), characterized by a third guide surface (A3) on the valve slide located in a constantly pressurized chamber (47) and directed in the same direction as said other drive surface (A2), the second and third guide surfaces (A2, A3) together being larger than the first guide surface (A1) and the first guide surface (A1) being larger than the third guide surface (A3), so that the slide (40) is moved in one direction when the first control chamber (45) is pressurized and the second control chamber (46) is pressure-relieved and moves in the other direction when the first and second pressure chambers have the same pressure level. Percussion device according to claim 1, characterized in that said first guide chamber (45) is arranged to be pressurized from one of the drive chambers (26) for the percussion piston for initiating the movement of the slide (40) that said one hall and said second guide chamber (46) are arranged to be pressurized from the other of the drive chambers (34) for the percussion piston to initiate the movement of the slide in the other direction. 505 171 Percussion device according to any one of the preceding claims, characterized in that the percussion piston (24) is guided in its front end and in its rear end and runs freely therebetween and a rear guide surface of the piston is defined between a surface (37) against said one drive space (26), which is a rear drive space, and a surface (36) towards the second drive space (34), which is a constantly pressurized front drive space, the guide channel (54) to the first guide chamber (45) having a port (56) arranged to open towards the front the drive space (34) and a port (55) arranged to open towards the rear drive space (26) and the guide channel (52) to the second control chamber (46) have a port (53) arranged to open towards the rear drive space (26) Percussion device according to one of the preceding claims, characterized in that it consists of a submersible drilling machine and the propellant used as drainage from the valve slide (40) is led through the piston to the drilling crown (14) of the submersible drilling machine as flushing medium.