FI63457C - ANORDNING FOER DRIVNING AV FOEREMAOL MEDELST TRYCK- ELLER DRAGKRAFT - Google Patents

Description

<g> SUOM I - FI N LAN D patent publication — patentkrft 63457.,, Θ

Kv.lk./lnr.Cl.JE 02 D 7/20 (y) Patent application - Patentansöknlng @ Application date - Ansöknlngsdag 28.11.77 (¾) Start date - Giltighetsdag 28.11.77 @ Published to the public - Blivit offentlig 0 ^ .06.78 © and date of publication—

Ansökan utlagd och utl.skriften publicerad 28.02.83

National Board of Patents and Registration © Patent granted - Patent meddelat 10.06.83

Patents and registries

Privilege requested — Begärd priority 0j.12.fo

Sweden-Sweden (SE) 761360H-3 (73) (72) Lar :; Gunnar Larsson, Läderu / it.travägen 97 »S-.175 70 Järfulla,

Ruo tr; L-Svi r i gc (SK) (rfh) Oy Kolo Tor Ah (Sh) Lal te euineiden junttaumi uekui by pushing or pulling ~

Anordning för drivning av förem & l medelet tryck- oiler dragkruft 1 f

The invention relates to a device for squeezing objects by means of pushing or pulling, e.g. when piling on the ground, wherein the squeezing member is adapted to periodically load the object.

For example, when piling or pledging, it is customary to use drop reflectors, vibrating reflectors or pneumatic hammers that strike directly against the object to be squeezed. However, the disadvantage of these known devices is that they have short impact times and cause high initial stresses on the object, which on the one hand is inefficient from the point of view of jerking and on the other hand can lead to damage to the objects to be jerked. It can happen, for example, that concrete piles bounce back after an impact and then crack at several points. Furthermore, high initial stress can lead to deformation and other damage. Another major drawback of existing equipment is that it causes significant noise.

Several attempts have been made to provide better and more efficient equipment. For example, it is known from the Swedish publication 6 3 4 5 7 388 647 to use a piston-cylinder device which operates with compressed air to raise the piston and dampen this downward movement. Through the compressed air, the piston loads the object all the time. However, lifting the piston requires large amounts of compressed air, which causes a lot of energy to be expended to compress the compressed air, which is less advantageous in terms of efficiency. Furthermore, compressed air causes certain noise problems and, in addition, relatively complex control automation is required to produce the desired push pulses. The object of the invention is to eliminate said drawbacks and to provide a device which is more efficient and quieter than known devices.

This is achieved according to the invention in that the jet member is arranged to be completely above the liquid surface at least at the beginning of its jet movement, that the groove forms a pressure chamber into which the liquid penetrating the jet movement forms a piston for compressing the gas cushion, preferably the air cushion, and during the attenuation of the compression movement of the member, to work together to maintain a sufficiently large amount of liquid in the container, whereby the movement of the compression member has complete or mainly braking before the contact of the compaction member touches the bottom of the container.

The co-operation between the compaction member and the fluid in the transfer member results in a longer and gentler compaction than before, while at the same time reducing the noise caused by the shocks.

It is also possible to provide the ram member and / or the transfer member with adjusting means to allow a fluid flow from the container adapted to the movement of the ram member.

A preferred embodiment is obtained if the compaction member can be moved with a certain clearance in the opening of the container and if there is at least one groove or notch at the closest end of the compression member, so that a gas cushion, preferably an air cushion, is formed in the notch. Such a device can be made very simple and reliable.

3 63457

Other features and preferred embodiments appear from the subclaims.

The invention will be explained in more detail below by means of an exemplary embodiment shown in the accompanying drawing. Fig. 1 schematically shows a device according to the invention, Fig. 2 shows on an enlarged scale a detail of Fig. 1 with the parts in a different mutual position, and Fig. 3 shows a variant of the device according to the invention.

According to Figure 1, a device 1 according to the invention is used for throwing an object, in this case a pile 2, into the ground. The device 1 includes a compression member 3, in this case a drop reflector, which is connected via a transmission device 4 to a power source 5 by means of which the compression member 3 can be raised to the desired drop height and periodically load the pile 2. The compression member 3 is controlled by to the transfer member 7, which in turn is fastened laterally with respect to the pile 2, e.g. by means of one or more stops 8.

The lower end 9 of the compaction member 3 is shaped at least during the final stage of the downward compression movement of the compression member to cooperate with the transfer member 7 to transfer the compression force to the pile 2. The transfer member 7 is formed by a container 10 9 when penetrating, a container 10 with a liquid 12 can penetrate to dampen the movement of the compression member. The end 9 of the ram member 3 and the transfer member 7 are adapted to co-operate and during the braking movement of the ram member to maintain a sufficiently high fluid pressure and a sufficient amount of liquid in the transfer device 7 to substantially stop the movement of the ram member 3 before contacting the bottom of the container 10.

The side of the head 9 facing the transfer member 7 preferably has at least one downwardly open notch 13. As can be seen from Figure 1, the compaction member 3 is located at least at the beginning of its compaction movement completely above the liquid surface 14. The diameter of the head 9 is preferably only insignificantly smaller than the diameter of the opening 11, and the sealing member 3 is thus insertable in the transfer member 7 with a certain clearance.

6 3 4 5 7

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In connection with the jerking movement, the jerking member 3 is caused to move towards the object. In connection with the drop reflector described here, this is done by releasing the compaction member from a suitable drop height. In this case, it is important that the guide 6, the compaction member 3 and the transfer member 7 are shaped in such a way that the compression member 3 can flexibly enter the container 10 in cases where it is initially completely outside the transfer member 7. provided with a chamfer 14 and further may have a corresponding chamfer 15 at the bottom of the end 9.

When the head 9 comes into contact with the liquid surface 14 and then moves downwards in the liquid 12, the liquid gradually penetrates the notch 13 (Fig. 2). Since the circumferential gap 16 between the head 9 and the container 10 is preferably narrow, only a limited amount of liquid has time to enter the gap. The liquid seal thus obtained retains a gas cushion 17, normally air, in the notch 13. The lower edge 18 of the head 9 compresses in its way a liquid which is mainly forced into the notch 13 and which, together with the other liquid, compresses the gas cushion 17. Thus a gradual braking of the compression member 3 is achieved

Experiments have shown that a drop reflector with a weight of about 4,000 kg and a drop height of about 0.5 m can be braked effectively so that it does not reach the bottom when the outer diameter of the head 9 is about 400 mm and the inner diameter of the tank 10. and about 402 mm.

The diameter of the notch 13 is then about 300 mm and the depth is about 200 mm. Water with a depth of approx. 250 mm is used as the liquid. In addition to a considerably longer-than-normal shock, about 50 ms compared to the normal about 10 ms, a very low sound level is also achieved.

To make it easier for the liquid to flow into the gap 16, the lower end 9 and / or the container 10 may be provided with one or more circumferential grooves 19 or the like (see Fig. 2).

It may also be desirable to allow the flow of fluid from the container 10 arranged in the movement of the compression member 3 by means of fluid flow regulating means, e.g. if only a small part of the end surface of the head 9 is provided with notches 13. Possibly notches 13 may be missing. One possibility is then to dimension the gap 16 so that the desired damping effect is achieved. Another possibility is to provide the container 10 or the sealing member 3 with the required number of suitably shaped and suitably positioned outflow channels, which may be provided with throttling means if necessary. An example of such a channel 20 is indicated by the dotted lines in Figure 2, where the channel is shaped so that the compressed liquid can flow back into the container.

It may be necessary to replace the fluid lost after one or more compaction movements. This can take place, for example, by means of a liquid filling element, e.g. by a liquid filling pipe 21, which can open at a suitable point. It may be necessary to provide cooling of the liquid in the tank, which may be by allowing the liquid to circulate in the cooling system and / or by cooling the tank 10.

The embodiment shown in Figures 1 and 2 can, of course, be modified in several different proportions according to needs and desires. Thus, for example, as shown in Fig. 3, the container 10 can be extended upwards so as to at the same time form the control of the compaction member 3. The shape need not be cylindrical, but other suitable shapes may be used. The liquid may preferably be water, but other liquids or liquid mixtures, such as a mixture of Gly-Kool and water, may also be considered.

The transmission device 4 may preferably be a hydraulic cylinder or the like attached at one end to the control 6 and / or to the transmission member 7 and driven by a hydraulic pump 5.

Thus, a very compact device can be obtained which operates quietly and efficiently without the need for compressed air.

The compaction movement of the compaction member 3 can, of course, also be effected in another way than by means of a free fall. For example, it is possible to expose the compaction member to the compressive forces of hydraulic members or the like. By appropriately shaping the transfer member 7, the device can be operated in such a way that it applies an attraction to the object instead of a pushing force.

In connection with the embodiment of Figure 2, where the gap 16 is narrow, it may be advantageous to provide a head 9 and / or container 10 with a non-return valve arrangement (not shown) to facilitate pulling the ram member up and out, allowing pressure equalization when the ram member is pulled up, but 6 63457 which remains closed during compaction.

The braking of the compaction member 3 in the fluid is e.g. depending on how the head 9 is shaped. The head 9 can be shaped, for example, so that it has a downwardly decreasing cross-sectional area, so that the liquid resistance gradually increases. Normally it is desirable to brake the compaction member to a stop before it contacts the bottom of the container 10, but in certain cases it may be desirable to allow the compaction member to strike the bottom of the container 10 or a suitable midsole at the end of the compression movement.

Claims (7)

7 ^ -7 a Γ H Claims: J A device for grouting objects (2) by pushing or pulling, e.g. piling on the ground, wherein the grouting member (3) is adapted to periodically load the object and at least during the final stage of its grooving movement to cooperate with the transfer member (7) to transfer the grouting force to the object, the transfer member is a container (10) having an opening (11) on the side facing the junction member through which at least a portion of the junction member can penetrate, the container having a fluid (12) for damping the jerking movement of the junction member; one groove (13) open towards the transfer member, characterized in that the compression member (3) is arranged at least at the beginning of its compaction movement to be completely above the liquid surface (14), that the groove (13) forms a pressure chamber into which the liquid penetrates the piston a gas cushion enclosed in the liquid groove, preferably i the compressor member and the transfer member are arranged to co-operate during damping of the compression movement of the compression member to maintain a sufficient amount of liquid in the reservoir so that the movement of the compression member has full or substantially Device according to claim 1, characterized in that there is only one groove (13) and that it is arranged centrally at the end of the ram member and the depth of which is preferably less than the diameter of the end of the ram member. Device according to one of Claims 1 to 2, characterized in that the arrangement between the ram member and the transfer element is such that a gap (16) with a substantially constant width is formed around the ram member. Device according to Claim 3, characterized in that the gap (16) is provided with at least one device (19) which impedes the outflow of liquid, e.g. in co-operating walls facing each other. Device according to one of Claims 1 to 4, characterized in that the ram member (3) and / or the transfer element 63457 (7) have adjusting elements (20) for enabling a fluid flow arranged from the container of the ram member. Device according to one of Claims 1 to 5, characterized in that the transfer element (7) comprises a device for cooling the liquid. Device according to one of Claims 1 to 6, characterized in that the ram member and / or the transfer element have at least one non-return valve which can open to facilitate retraction of the ram member (3) after the ram movement, but which is closed during ram. 9 Patent: 6 ^ 457