KR19990036100A - Hydraulic Strike Device - Google Patents

Abstract

A device that selectively generates two strokes by hydraulic pressure and is equipped with oscillating motion pistons (5) and (19), wherein the stroke of the piston is controlled and maintained by means of a reversible valve (12). And acting on the symmetrical ends of the pistons 5, 19, which act on the transverse plane of the piston and are operated as stroke transmission surfaces, wherein the pistons 5, 19 are ring-shaped pistons, Cylindrical spaces 3 and 4 are formed in the annular space, and at least part of the stroke transmission bodies 2 and 22 serving as the attachment body to the tool 1 or the target are disposed.

Description

Hydraulic Strike Device

An apparatus for generating a stroke by rotating an eccentric mass is known from, for example, Finland patent application 935536. Optionally, the stroke is sent in two directions, up and down. Using multiple rotating masses, the impact of the stroke is sent very quickly in the desired direction. Instead of the compensation mass, part of the impact of the stroke remains in the opposite direction. While driving a profile with such a device to the ground, the stroke is sent very quickly so it is sent over a short period of time on the profile. By the starting friction stroke, the possible influence of the profile and the mechanical friction must be overcome.

In addition, in the hydraulic impact hammer known from Finnish application 843015, the piston is accelerated by hydraulic movement to strike the impact transmission structure. Also in this structure only one stroke occurs at a time, and try to absorb the impact of the stroke by the movement of the mass, which also includes the cylinder space for the piston.

With regard to the impact device, absorbents are known in which the strokes are absorbed and transferred by the profile for some long period of time. As such elements, wooden intermediates are used among others. Using the absorbent, the stroke is transferred into the profile as one impact. And, because the amount of absorption is large, the starting friction of the profile cannot be overcome and the stroke remains forceless. On the other hand, because the duration of the stroke is short instead of absorption, the impact of the stroke stops before the influence of the profile and the profile is not necessarily driven forward by the stroke.

To drive a long object to the ground, the striking device must be raised high above the top of the object while the device must be lowered back on the next stroke. This requires an outreaching crane and a complicated start, where long objects, for example piles, are built first using auxiliary equipment. In addition to gripping the file, the striking device lifts the long file upright onto the ground.

The present invention relates to an apparatus for generating a stroke by a piston in linear motion according to the preamble of claim 1 of the appended claims.

1 is a cross-sectional view of a striking device with an internal moving mass and an external piston,

2 shows a mass with a second moving mass,

3 shows a liquid mass, and

4 shows a striking device having an opening through a center thereof.

In order to solve the above-mentioned present problem, a striking device having the features described in the appended claims is disclosed.

An advantage of the present invention is a two-stage or multistage impact of a new type of stroke that is "talked" to a vibrating state or motion in which the object at an initial stage of shock peaks to overcome the starting friction at least in the first place. With the structure, the timing of the shock peak can be adjusted immediately after the previous peak so that the object is still moving or vibrating and the starting friction is overcome. By this procedure the impact of the later shock peaks is used as completely as possible for the forward movement of the object.

By the annular piston and the striking device, the striking of the profile in low space is improved when the striking device is against the middle part of the profile instead of the top of the profile and does not increase the overall weight. By means of a hydraulic excavator, long piles, beams, and profiles can be driven when the reach of the excavator is not limited. Strikes in the profile where the walls are thin and easily buckled are possible when the strike can always be carried out close to the ground in the change of grip. Lifting the profile from the ground is possible using an excavator by replacing the scoop with a striking device that can be tilted according to the scoop, where the profile can be gripped by the striking device in its own middle part, where the The reach is enough.

The invention is described below in connection with the accompanying drawings.

1 shows a hydraulic striker with ram 2 as an inner part provided with an annular shoulder 2, from which the stroke is transmitted in one of the longitudinal directions. The shoulder 2 around the ram has a movement distance between the stop surfaces in the piston 5. The upper part of the ram is a flange with a shoulder 8 against which the piston 5 having an annular surface strokes upward. The lower part 8 of the ram is a flange against which the piston 5 with the stop surface 9 strokes downward. The lower part of the ram has a pile-beating head 1 with a tightening jaw proven as an appropriate striking mechanism in this embodiment.

A cylinder space is formed inside the piston 5, and hydraulic pressure is transferred to the inside. The rod has a shoulder 2 which divides the cylinder into two parts 3 and 4 and transmits an axial force to the rod.

The driving of the piston is achieved by a control system with a valve 12, which most appropriately regulates the direction of supply of fluid to the channels 10, 11 by means of an electric steering device. The valve 12 has a reverse function, which allows it to be operated by observing the position of the piston every hour. The hydraulic source is a pump 13 and a hydraulic accumulator 14 is attached to the pressure line to ensure the speed of the piston movement, generating an acceleration movement of the piston and reducing the influence of pressure shock in the system.

The device according to the invention shown in FIG. 1 is provided with a piston having an annular free space in which the mass 7 moves. The mass 7 is a solid ring, whereby a free movement space of distance X is arranged relative to the piston. The piston 5 strokes downward and is accelerated to direct pressure into the chamber 4. By using the hydraulic accumulator 14, the stroke can be accelerated, whereby the piston has a sufficient final speed before the stroke hits the shoulder 9. The mass 7 follows the piston 5 and in its second stage a stroke of its own with respect to the lower part of the piston 5 occurs against the shoulder 9. The mass is for example a solid, such as steel or lead, and the piston comprises several parts, for example an individual outer shell 6. In one embodiment, the mass may also be a ring that entirely surrounds the outside of the piston, the length and thickness of which is easily adjusted, and thus the movement distance X and the amount of mass can be easily adjusted as well.

In an embodiment of the invention, the second stage stroke is delayed in leading the mass 5 to the travel distance X. The device generates two consecutive sharp strokes, whereby the first stroke moves the target profile and the second stroke generates a driving shock. In this basic embodiment, no absorption is present. The time between successive strokes is adjusted by changing the travel distance X or the piston speed. The mass strikes the piston while the target profile is in motion or in the vibrational state generated by the stroke.

For example, in the embodiment of the solution for FIG. 1, an absorbent element is added to the shoulder 9, thereby lengthening the effective time of the stroke in both steps. For example, cushioning elements such as known pieces of wood are used.

In another embodiment, in the movement of the mass 7 a space is formed for the second mass 15, which space is the movement distance X of its own inner mass 7 as shown in FIG. 2. '), And this mass 15 is delayed after the mass 7 makes a stroke and exerts a stroke.

In a fourth embodiment, the mass is fluid 16 as shown in FIG. The liquid flow can be delayed by the choker 17, where the pressure stroke can also be delayed. On the other hand, the choker may slow down the flow of liquid during the return movement, but the effect is small if the choke point is adjacent to the stroke wall, ie the piston lower edge. Water, mercury or other heavy fluids can be used. Instead of the fluid, the mass may be granulated, whereby the stroke is significantly absorbed compared to the solid mass. The granulated material used can be electrically charged, so that steering motion of the granulated material is pushed and pulled towards the piston head, for example, is achieved, and the return movement of the granulated material or its movement in the stroke direction is achieved. Can produce effects.

Following the return movement of the piston, the mass 7, 16 or mass 7, 15 moves across the top of the piston, where it arrives without delay and the piston has already stopped at the upper position or the corresponding upper return point. When the piston moves the mass according to the law of continuity. When this mass strokes the piston upper part, it is an appropriate time to start the piston reciprocation for a new stroke. Adjustment of the valve 12 is performed such a delay occurs. After this stroke, the piston return reciprocation begins when the mass strikes the lower part of the piston.

By the combination means of the above-described embodiments and by adding the absorbing means, the solution is solved, as in the first embodiment, the continuous steep stroke is changed to a longer duration stroke. Of course, with other structures according to the present invention, a properly formed stroke can be generated.

The device of FIG. 1 can be adjusted to make the stroke movement in the opposite direction and according to the invention only by changing the control of the valve 12. The tool 1 can also be replaced by another stroke tool, for example a stroke pike.

4 shows an impact device with an annular body 22. An impact profile, such as the tube 25, runs through the body and is disposed from the opening so that the impact device is located around the contour. This impact device is equipped with a ring-shaped piston 19 that moves around. The alternating piston movement is achieved by a control device as shown in FIG. It is possible to apply a stroke in both directions by this piston.

The impact profile 25 is centered on the inner surface of the body 22. The profile is attached by a movable wedge 20 that squeezes against the profile body 22. The wedge 20 is for example moved by means of a hydraulic cylinder 21. The stroke of this piston 19 increases the wedge action and the impact wave profile reliably strokes the body.

The shape of the wedge part can be changed according to the profile to make it possible to stroke the different types of profiles, pipes, piles, beams, etc., simply by changing the wedge part.

If it is bent at the wedge as the support for the profile 1 or at the outer surface of the profile, for example by the wedge, by some power means, for example by means of a hydraulic cylinder 24 Support elements 23 may be installed which are tightened or expanded. The support may be placed or moved to the required position by a wire rope or winch.

The impact device is supported by means of a rubber pillow attached to the outer body of the impact body 27. The outer body is attached to the excavator instead of scoops.

Claims (9)

A device which selectively generates two strokes by hydraulic pressure and is provided with oscillating motion pistons (5) and (19), the stroke of which acts on the intersection of the pistons and is operated as a stroke transmission surface. (5), the apparatus is maintained by adjusting the hydraulic pressure by means of the reversible valve 12 to act on the symmetrical ends of (19), The pistons 5 and 19 are ring-shaped pistons, and cylindrical spaces 3 and 4 are formed in the annular space thereof, and the stroke transmission body 2, which acts as an attachment body to the tool 1 or the target, At least a portion of 22) is arranged. The device according to claim 1, wherein the center of the device is open to place an elongated object (25), which is driven by the device to a stroke transfer position. The method according to claim 1 or 2, wherein the stroke transmission body (22) is configured to fix the parts (20, 21) for attaching the impact device to the periphery of the object (25) taken through the device. Characterized in that the device. The method according to any one of claims 1 to 3, wherein the piston (5) comprises masses (7), (15) and (16), which are assembled to move at a limited distance in the direction of impact with respect to the piston. The mass is adjusted to be stroke reciprocated and accelerated along the piston and is most appropriately pushed by the piston and in the mass, the movement distance X in the direction of impact is equal to the reciprocating stop before the piston makes a stroke. The device is arranged so as not to strike the stroke. The device according to any one of claims 1 to 4, wherein the mass is an annular part of the piston. 6. The device according to claim 1, wherein the mass is a liquid (16), a granule or a solid (7) aligned with the inner surface of the piston. 7. 7. Apparatus according to any one of the preceding claims, wherein absorbing means are provided for extending the stroke action time caused in connection with the mass in relation to the mass. 8. Device according to one of the preceding claims, characterized in that a braking means (17) is provided for causing the mass in liquid or granular form to at least have a braking action in the movement in the direction of impact. The movement distance (1) according to any one of claims 1 to 8, wherein the stroke of the mass (7) occurs on the piston (5) when the stroke targets (1, 2) are under vibrational conditions generated by the piston stroke. X) is selected small.