DE2714921A1 - Ram for soil sampling - uses compressed air fed to striker chamber of piston having hollow rod - Google Patents

Abstract

The ram establishes soil properties or soil samples. A hollow piston rod is directly connected with the ram and divides the housing into a striker and return chambers. The side of the piston which is active for the striker stroke is constantly exposed to the compressed air feed. The striker chamber has a small working surface and the compressed air take-off from the larger surface return chamber is via the hollow piston rod. The housing or the piston forms the ram bar. During the return stroke, the striker chamber is connected with the return chamber by recesses in the piston. At the end of the return stroke, it is separated from the return chamber.

Description

Title: Rammer

The invention relates to a ram for determining properties of the soil or for the extraction of soil samples, the one inside a housing displaceably guided, on one with the piling object at least indirectly connected arranged hollow piston rod, the housing in an impact and a return chamber having dividing piston, whose effective side for the stroke stroke constantly is exposed to the compressed air supply in an uncontrolled manner.

For the soil and subsoil investigation, ramming is carried out with a constant Impact energy used. Such rams have a specified limited ramming capacity, to determine the penetration resistance from the number of blows for a certain driving distance to be able to determine. In contrast, ramming is used to obtain soil samples great performance is required. Combustion, electric or compressed air rams are used for this purpose known with compressors. These have a larger number of strokes, but none constant, precisely defined impact energy.

So on the one hand, exploratory rams count for the purpose of determination of properties of the ground or the subsoil to the state of the art, but which not at all or only to an uneconomical extent for the extraction of soil samples can be used. On the other hand, ram drills are known with which earth samples can be obtained due to their great performance, but which are unsuitable for ramming. In addition, these rams are relatively heavy, which consequently has a negative effect on geological investigations in difficult terrain.

One known type of hammer drill has a long cylindrical one Housing on, which is connected at one end to the piling object. In the opposite Front side, however, is a hollow piston rod inserted in the center. The piston rod, which is about half as long as the housing, is used to supply the fresh compressed air, while the used exhaust air is passed through openings on the side of the Housing is derived in the area of the introduction of the piston rod. Within the The housing is the piston that interacts with the piling object and forms the Ranmbr slidably fed, which is also sealingly displaceable relative to the piston rod is. The piston rod can dip into a central longitudinal bore of the piston.

The control of the ram drill is done in such a way that the over The compressed air supplied to the piston rod initially takes the stroke of the under its own weight falling piston accelerates. At the end of the stroke, the compressed air is in a Annular space between the piston and the housing transferred and here to expand brought to thereby perform the return stroke of the piston. At the end of the return stroke and only then does the pushing out take place over the same piston path of the stroke stroke of the air used, but for a relatively long period of time.

The principle of expansion control is therefore applied, with largely dynamic forces are effective. These have the consequence that the reversal of the piston from the impact stroke to the return stroke and vice versa essentially takes place depending on the path, but the percussion piston itself as a result of the compressibility of the working medium moved further beyond the reversing position. Also is the air consumption is very high. With an expansion ratio of 1: 1.8, that too at a pressure of 10 bar can practically not fall below, a Liters of air produce only 44.2 Nm, whereby isothermal expansion is assumed. With polytropic expansion, the result is even worse. Despite the high pressure is therefore only a minor one Achievable performance, and also the pressure loss in the supply line is high due to the high air consumption is.

In a known probing ram to determine the properties of the ground, the housing forms the ram and the one connected to the piling object Piston rod is the guide part for the housing. The piston is at the end of the piston rod attached.

So it is a so-called free-fall ram which the ram is formed solely by the weight of the cylinder will. However, it can only be used in a targeted manner because it is one of the DIN regulations dependent stroke length and thus a certain weight. Have free fall rams no back pressure either. The ram weight, i.e. the housing, is raised during the impact stroke accelerated only by gravity. Bigger hits and high performance cannot be reached with such probing rams.

The invention is accordingly based on the object of a ram to create the genus presupposed at the beginning, which both with a constant, in the case of small numbers of blows, precisely defined impact energy as well as on the other hand with high piling capacities and larger numbers of blows with small dimensions and Weights can be operated.

According to the invention, the solution to this problem is characterized by that the compressed air supply via the housing in the provided with a smaller effective area Impact space and the compressed air discharge from which has a larger effective area The return space takes place via the hollow piston rod, the housing or the piston forms the ram acting on the ramming object, and that the impact space through channel-like recesses provided in the piston during the entire return stroke the return space air-conducting connected and at the end of the return stroke under connection of Return chamber to the hollow piston rod can be separated from the return chamber.

Regardless of whether the housing or the piston is used as a battering ram has, according to the invention, equipped with a constant pressure or full fill control Rammc has the advantage that the stroke stroke of the CehSust or the piston of the LlnXe can be determined exactly. There are always static conditions, where the perfect stroke limitation of the housing or the piston with continuous uncontrolled Pressurization of the impact roughness with compressed air exclusively through the piston provided Channel-like recesses in cooperation with the one guide element for the piston or hollow for the housing forming the drainage of the used air Piston rod is effected. The safe stroke limitation and reversal have the advantage of that the impact speed of the ram on the ramming object is independent of energy, Weight and stroke length always remain the same. Will more air and this if necessary also supplied with a higher pressure, it has a geared towards it by itself higher impact speed result, which in turn, too, accordingly higher number of strokes resp.

Impact performances or impact energies leads.

The one on the stroke stroke beyond the free fall through the compressed air accelerated ram (housing or percussion piston) makes the ram with regard to their Impact energy regardless of the stroke length required by any regulations and weights. It also makes it more efficient because it does so even with only a slight excess of pressure or a small amount of compressed air is possible, although a high number of blows is slow To achieve impact energy and above all a constant impact energy that can only be achieved by depends on the diameters and the specified stroke in the ram.

In addition, it is essential that the subject of the application find use both as a probing ram and as a hammer drill can be used, regardless of whether the ram is vertical or at an angle Working towards or sideways. Your independence from the terms of the Free fall finally makes it possible to define the ram depending on the Effective area ratios freely usable to use. It is therefore used as a hammer drill can also be used in such an embodiment in which the hammer drill itself is lowered into the borehole, e.g. by means of a cable pull or the like. The ram work underwater. liierfür it is only necessary to connect the compressed air inlet and to connect the compressed air outlet to lines above the water level flow out.

The invention advantageously makes use of a known principle benefit, namely the use of the weight and the frictional force of the piling object in the ground to absorb the back pressure of the ram. As the hollow piston rod at least is indirectly connected to the piling object, a high piling performance can accordingly the weight and the frictional force of the piling object in the ground. It short overall lengths and short strokes are achieved. The total weight of the ram is only little bigger than the battering weight. The impact energy is high with only low Air pressure. Even with a small number of blows, a constant single blow energy is guaranteed. If, for example, the ram is connected to an upstream air chamber with only that much compressed air operated so that a slow return takes place, then the ram regulates the operating pressure even while maintaining a constant impact energy. On the other hand, the weight des Ran.nba'rs an additional weight is added, then it is also in the same proportion the climbing pressure and thus the impact energy improved.

However, the impact speed of the ram remains constant and depends only on the exact relative dimensioning of the effective areas of the space and of the return space.

In this context there is a preferred feature of the invention in that the square of the inside diameter of the housing less the square the outer diameter of the piston rod in the length section delimiting the return space ir, relation to the square of the outer diameter of the piston rod in which the piston rod is located limiting length section, reduced un the square of the outer diameter of the Piston rod in the length section delimiting the return space is roughly 1: 2 is sized. This essential feature allows it to be carried out with just a single pile to realize all those ramming probes which, according to the regulations, all have one Should have an impact stroke of 0.5 m, but have different pile weights.

This means that the impact speed of the battering ram also remains at different weights and thus in the same ratio changed impact energies or rising pressures always constant and only depends on the dimensions of the effective areas away.

An advantageous embodiment of the invention is characterized in that the hollow piston rod is connected directly to the piling object and which acts as a ram housing is guided on the piston rod, the piston limited sliding by the housing between two stops on the piston rod can be moved back and forth and via the recesses provided in it when plant at one stop with the closure of the return space with the piston rod connecting transverse bores the impact space with the return space and when planted on the other stop connects the return space with the piston rod.

The hollow piston rod provided for the discharge of compressed air is in this Embodiment coupled directly to the piling object.

It is used for the vertical guidance of a closed housing, its both end faces are penetrated by the piston rod in a sealing manner. The piston is approximately in the middle length section of the Piston rod arranged and there guided to a limited extent movable on the piston rod between two stops. the Entrainment of the piston in one direction or the other until it rests on the the respective stop occurs exclusively through the housing. The training of the channel-like recesses in the piston and the corresponding connecting bores between the return space and the interior of the piston rod as well as their mutual Allocation is made so that an exact reversal in both end positions of the piston from the impact stroke to the return stroke and vice versa is guaranteed, with the switching is guaranteed even with only a low return speed of the housing. The reason for this is that as a result of the differently sized effective areas of the return space and the stroke space in the switchover position immediately a large one Power surplus is effective in the return space. Through this dimensioning and through the Formation of the piston and the arrangement of the recesses in the piston and the corresponding Cross bores in the piston rod cause the piston or housing to get stuck excluded in top dead center even with a small number of strokes.

According to the invention, the differentiation of the effective areas of the impact and return space by a gradation of the outer diameter of the piston rod in Movement range of the piston recessed according to the gradation formed. The stop that is closer to the piling object is approximately trapezoidal in cross section Annular groove upstream, which then allows the compressed air out of the impact space Flow over the channel-like recesses in the piston into the return space. If the piston is then pressed against the upper stop by the housing, formed e.g. by a clamping ring inserted into an annular groove in the piston rod is, the trapezoidal ring groove of the corresponding wall sections of the Overwhelm the piston, which is then attached to an adjacent ring collar of the Piston rod create a seal so that the return space is clearly separated from the impact space is. In this position, however, are the channel-like recesses in the piston connected to the cross bores of the piston rod, so that the one located in the return space used air now into the hollow piston rod and from there into the environment can flow away.

It is of particular importance in the context of the invention that the back pressure or impact pull, i.e. the force that strives for the entire ram to be pulled out of the ground together with the piling object, perfectly manageable is. If a slow return of the ram is preferred, then that of the ram is preferred Distance covered further after the reversing process is almost zero. This additional Weg assumes somewhat larger values when there is an increased air supply higher impact numbers and energies can be achieved and thereby also the piling performance becomes higher, but there is no hard hitting of the ram at the end of the return stroke. For this purpose, the excess force after driving over the control edges is too large and too effective immediately.

Another and equally advantageous embodiment of the invention, which also has the advantages described above, identifies in that the hollow piston rod is directly connected to the piling object and the effective ram housing is guided on the piston rod, wherein the Piston fixed on the piston rod and one on both sides through the housing between two stops provided on the piston rod control disk is limited, the spacing elements penetrating through the piston parallel to the piston rod are distanced from each other.

In this embodiment, the piston is accordingly on the piston rod immovably set. The connection of the impact space with the return space resp. the separation of these two rooms as well as the connection of the return room with the Inside the piston rod and the separation of this connection is here by two control disks arranged on both sides of the piston and movable relative to it causes that are spaced from each other by such bolts, for example, whose Length is greater than the thickness of the piston. They are also, xe, enabove the piston slippery «. The channel-like recesses in the piston consist of several Axial bores running parallel to the piston rod with the same spacing are arranged on a circle. At the end of the return stroke, the rammed object is located adjacent control disk positively in a recess of the piston and versnerrt thereby the axial bores in the piston between the percussion and return space, while the control disc facing away from the piling object, the fluid bores in the piston rod release and thereby the return space with the exhausted air Twist the piston rod. At the end of the stroke, however, it blocks the piling object remote control disc the connection between the return space and the piston rod, trend, the control disk adjacent to the Ra; nmobJekt is now again always uncontrolled with compressed air pressurized impact chamber connects with the return chamber.

In the context of this embodiment, too, according to the invention Differentiation of the effective areas of the stroke and return space by a gradation of the outside diameter of the piston rod in the range of motion of the control discs.

In order to also use the ram according to the invention as a hammer drill with large piling performance and small dimensions the advantages of a known per se To secure high-performance ram, the invention provides that between the ramming object and the control disk located above on the side facing the piling object with a at the end of the return stroke in a recess d housing dipping annular Vereren approach i, t. By immersing the approach in the housing recess In the top dead center, a smooth switchover is achieved, although taken into the knob it can be that the battering ram moving further through the switchover position causes a, relatively gifted, covered a little longer distance. It is thus achieved that the fr Every ratio of the return force to the weight of the oral area, at which a maximum number of strokes is set that can be used, in order to achieve the greatest possible performance with the smallest dimensions.

Another advantageous feature of the invention that both at iner ram with sliding piston as well as with fixed piston and then on both sides arranged .Steuerscheiben is used, characterized in that between the free end of the piston rod and the housing face an elastic return means is incorporated.

This return means is preferably a helical compression spring educated. The compression spring on the one hand supports the surface in the impact space and on the other hand, keeps the amount within limits that the battering ram over the switchover position also wants to slide further, so that a hard interaction of housing and Piston is prevented. When using this spring for ramming or horizontal ramming a further increase in impact energy can be achieved because of the changeover existing climbing pressure, which also determines the impact energy, is increased by the spring will.

With the help of the spring, the value of the impact velocity can be determined corresponding substitute free fall height of Housing that in principle determined by the dimensions of the l, number surfaces of the impact and return space can still be enlarged.

The one used to guide the housing and connected to the ram object The hollow piston rod also allows long ramming pieces to be repositioned without converting the ram itself. Two-part inserts can be used here arrive, which are fitted into corresponding grooves of the Ges'ringes. Because the compressed air is fed to the housing and the piston rod is freely rotatable in the housing, needs also the compressed air supply line not to be removed during operation, if E.g. rod pieces have to be readjusted or the rod must be twisted must to retighten the thread.

According to the invention it is also conceivable that the piston rod is closed at the free end and the housing in the remote from the piling object End section not penetrated, the exhaust opening in the adjacent to the piling object nd section is provided. In this case, the housing is also closed at the top. The hollow piston rod then expediently only extends as far as the upper stop of the piston or up to the control disc facing away from the piling object.

Another embodiment that is also advantageous for certain applications as the embodiments described above is characterized according to the invention in that the movable within the housing and on the relative to the housing Piston rod guided piston forms the ram, with the return space on the one hand with the impact space and on the other hand with the piston rod connecting recesses axially movable in the piston by one between two stops and under the influence an elastic restoring force provided control pin can be locked.

It is essential that the effective area of the return space is larger than the effective area of the impact area by such an amount, which is roughly the square of the outer diameter of the piston rod, multiplied by the fourth part of pi. A ram with the above features is therefore can then be used with great advantage when this ram is lowered into a borehole or is used for horizontal or inclined holes. Even with this one Embodiment is guaranteed that the axially movable control pin in the piston in both switching positions the channel-like recesses in the piston are so precise prevents the piston from getting stuck in one of the two end positions is.

In this regard, it is also provided according to the invention that at the end of the stroke of the control pin by the piling object against the effect of the elastic Restoring force is displaceable and the connection between the return space and the piston rod locks. The elastic restoring force is also expedient here formed by a helical compression spring, which during the stroke stroke the control pin pushes forward beyond the face of the piston striking surface.

It is then advantageous that the control pin at the end of the return stroke through the free end of the piston rod in cooperation with the elastic restoring force is axially displaceable in the direction of the piling object and the connection between locks the impact and return space.

In both cases, only the control pin serves to on the one hand the connection between the impact and the return space and on the other hand the Connection between the return space and that of the exhaustion of the stale air Serving piston rod to open and lock. The piston punch interspersed in this embodiment the piston over a substantial part of its length.

If a ram rCemän of the last described embodiment When used in a borehole, it can be advantageous to attach the piston rod a suspension cable and an elastic one between the housing and the piston rod ückstellmittelel is incorporated. This resetting means can be achieved by a screw Be formed compression spring between a finger collar of the piston rod and is incorporated into the bottom of a recess arranged in the housing. Has, for example a ram fixed in the borehole, the xollen rod can now be against the Force of the helical compression spring can be pulled up through the suspension rope. Through this changes the Laze of the free end of the piston rod with the result that the Control pins no longer reversed by the piston rod at the end of the return stroke can be. Rather, the air pressure keeps the control pin in place so that the piston pushes up against the housing, loosening the seized Rammoboektes causes.

In this relatively simple manner, rope breakage and loss can occur of the hammer drill can be avoided.

Is the frictional force of the piling object in the ground at the beginning of the ramming not yet available, so it is advisable to start the first blows with less force to then carry out the blows with increasing friction of the piling object in the ground to be able to strengthen accordingly. This possibility is thereby made according to the invention realized that the piston rod acting as an exhaust pipe with a controllable Throttle is provided.

The throttle can be formed, for example, by a screw that holds the Keeps the exhaust port partially closed at the beginning. In this way, the throttled the first ramming strokes and thus slows down the return speed, until there is sufficient friction between the piling object and the ground Back pressure a sufficient force counteracts it.

The invention is illustrated below with reference to in the drawings Embodiments explained in more detail.

It shows: Fig. 1 a ram in vertical longitudinal section, with the left the mid-vertical an operating position at the end of the stroke and on the right the Is illustrated mid-vertical at the end of the return stroke; Fig. 2 is another Embodiment of a ram in vertical longitudinal section, also on the left Mid-vertical an operating position at the end of the stroke and to the right of the mid-vertical is shown at the end of the return stroke; Fig. 3 shows a third embodiment of a Ram in vertical longitudinal section with an operating position at the end of the impact stroke; 4 shows the ram according to FIG. 3 in a vertical longitudinal section with an operating position at the end of the return stroke and FIG. 5, the ram according to FIGS. 3 and 4 in the vertical Longitudinal section in an operating position at the end of a pull stroke.

Fig. 1 illustrates a with the help of a probing ram 1 in the ground 2 introduced piling object 3, for example a probing rod, for Determination of the penetration resistance.

At the free end of the probe rod 3 is an axial extension multiple stepped hollow piston rod 4 placed. To this end, the Piston rod has a recess 5 into which the end of the probing rod is largely form-fitting intervenes. The piston rod is coupled to the probe rod by a Cross bolt 6.

This coupling area of the piston rod 4 becomes the free end limited by a conically drawn-in circular ring surface 7, which in a following described in more detail the anvil for the below also in more detail described battering ram forms. The anvil 7 is joined by a tapered diameter Length section 8 of the piston rod, the length of which is approximately half the length of the entire Piston rod corresponds.

In the middle length range of the piston rod 4, 9 is a cross-section approximately trapezoidal ring groove / incorporated, which is attached to the free end of the piston rod an annular collar 10, which is tapered again in diameter, adjoins it. In connection the longitudinal section 11 of the piston rod located there is again on the ring collar offset in diameter. However, this diameter remains until the end of the piston rod the same where a radially projecting annular collar 12 then limits the piston rod.

The piston rod 4 is one in diameter over its entire length constant bore 13 penetrated.

In the area of the annular collar 12, the bore is open, in the area of However, the lower recess 5 is closed. Above the middle ring collar 10 are A plurality of transverse bores 14 are arranged in the wall of the piston rod.

A cylindrical housing 15 is axially displaceable on the piston rod 4 guided. For this purpose, the two end faces 16 and 17 of the housing point accordingly the outer diameters d2 and d1 of the two piston rod length sections 8 and 11 designed openings 18 and 19, respectively. These openings are opposite the piston rod sealed. It can also be seen that the from the lower length section 8 penetrated opening 18 widened conically in the direction of the piling object 3, this conical extension 20 of the conicity of the anvil 7 is adapted.

The end face 16 of the housing 15 is considerably thickened and has a recess 21 directed towards the interior of the housing. One opens into the recess Transverse bore 22 corresponding to the arrow Z of the supply of compressed air into the housing serves. The opposite end face 17 is also opposite the wall thickness more educated. However, it is only about half as thick as the one with the anvil 7 cooperating end face 16. Also in this end face is an inwardly directed one Recess 23 is provided.

A piston 24 is delimited in the middle length range of the piston rod 4 reciprocally guided. The piston is opposite to the housing 15 as also sealed against the piston rod. The piston thus separates the interior of the housing into an impact chamber 25 connected to the compressed air supply Z and into a return space 26. It has several bores 27 lying on a circle, however, they do not penetrate the piston along its entire length. The holes open on the one hand in the return space 26 and on the other hand in a recess 28, which radially inward is open towards the piston rod. The turning is through towards the rammed object 3 an annular collar 29, the inner diameter of which corresponds to the outer diameter d3 of the Ring collar 10 corresponds to the piston rod. To the free end of the Towards the piston rod, the turning is also limited by an annular collar 30, the inside diameter of which is the outside diameter d1 of the upper length section 11 corresponds to the piston rod. The ring collar 30 is on the top and bottom to the outer circumference of the piston 24 is discontinued.

The displacement of the piston 24 is on the one hand by the free End of the piston rod 4 facing circular ring surface 31 of the ring collar 10 in cooperation with the circular ring surface 32 of the ring collar 30 of the piston pointing towards the ramming object 3 and on the other hand by a clamping ring 33 fixed on the piston rod in cooperation with the circular ring surface 34 of the ring collar pointing towards the free end of the piston rod 30 determined.

It can also be seen from Fig. 1 that between the ring collar 12 at the free end of the piston rod 4 and the outer surface facing this annular collar 35 of the housing end face 17 is a helical compression spring surrounding the piston rod 36 is arranged.

Fig. 1 shows the impact position to the left of the vertical center line 37 the probing ram 1. In this impact position, the housing 15 lies on the lower one Length section 8 of the piston rod 4 adjacent conical circular ring surface 7 and the piston 24 lies with the circular ring surface 32 on the middle ring collar 10 of the piston rod at.

According to the arrow Z to the loft 25 continuously supplied In this impact position, compressed air reaches between the annular collar 29 of the piston 24 and the bottom of the trapezoidal groove 9 of the piston rod 4 through over the inwardly open recess 28 and the axial bores 27 in the piston in the return space 26. The incoming compressed air thus acts on both Piston sides, wherein the housing 15 is both under the piston force, which results from the value D (Inside diameter of the housing) to d1 (outside diameter of the upper piston length section 11) results, so that is the return surface, as well as under the piston force, the from D to d2 (outer diameter of the lower piston rod, length section 8), So that's the clubface that gives you. For the rise of the housing with G kilopond Weight is therefore an annular area A F corresponding to d2 to dl. An increase of the housing takes place when the rise pressure is P = G: a F.

When the housing 15 rises, the piston 24 is drawn in its Position due to the effect of the ring surface d3 (outer diameter of the ring collar 10) d1 held. Only when the inner surface 38 of the lower housing face 16 on the piston comes to rest, this is from the housing in the direction of the free end of the piston rod 4 taken away. In doing so, the up to then closed by the ring collar 30 of the piston Cross bores 14 in the piston rod are connected to the recess 28 in the piston and by the sealing contact of the ring collar 30 of the piston on the ring collar 10 of the piston rod the connection between the impact space 25 and the return space 26 is interrupted.

As a result, the piston immediately shoots up until it hits the clamping ring 33 arrives at the plant.

This operating position is now to the right of the vertical center line 37 illustrated. There is a direct connection between the return space 26 via the bores 27 and the recess 28 in the piston 24 with the transverse bores 14 in the piston rod 4 and thus with the longitudinal bore acting as an exhaust line 13 of the piston rod. The compressed air in the return chamber can now move in the direction of of arrow A so that the effective area of the return space is depressurized.

In contrast, the effective area of the impact area is now fully loaded, so that the stroke takes place, with the conical enlargement 20 in the lower housing face 16 strikes against the conical annular surface 7 of the piston rod 4. Just before contact the piston 24 is also supported by the inner surface 39 of the upper end face 17 of the housing taken along and moved into the position shown to the left of the perpendicular 37 is. The work cycle is repeated.

The embodiment according to FIG. 2 largely corresponds to that 1. The only difference is the design of the piston 40 and the length section of the piston rod 41 cooperating with the piston.

The drawing illustrates that the piston 40 is now firmly on the piston rod 41 between a shoulder 42 of the piston rod and a snap ring 43 is arranged. The piston can no longer be shifted to the left with respect to the piston rod guided. It has axial bores 44 arranged on a circle, of which several, e.g. three, slidably penetrated by bolts 45, but sealingly, the length of which is greater than the thickness of the piston. These bolts are between two sides of the piston arranged control discs 46 and 47 incorporated. The control disk 46 is located in the impact space 25 and the control disk 47 in the return space 26. It can be seen that the upper control disk 47 between a shoulder 48 the piston rod 41 and a stop ring 49 on the piston rod and the lower Control disk 46 between a recess 50 in piston 40 and a shoulder 51 the piston rod can be moved back and forth.

It can also be seen that the lower control disk 46 is an annular Approach 52 is assigned, which is in a recess 53 on the inside of the lower housing face 16 can immerse.

In the striking position illustrated to the left of the vertical center line 37 the compressed air reaches the arrow Z via the transverse bore 22 and the recess 53 into the percussion chamber 25, from where it also passes through the axial bores 44 in the piston 40 enters the return space 26. Due to the differently dimensioned effective areas of the Stroke space and the return space, the effective force in the return space is greater as the effective force in the stroke space, so that the housing 15 on the piston rod slides along upwards. When doing so, the inner face 38 of the lower end face of the housing arrives 16 with the lower control disk 46 in contact, it takes it with it for so long to the control disk as shown on the right side of the vertical center line fully rests in the lower recess 50 of the piston 40 and thereby the axial bores 44 locks in the piston, so that the connection between the stroke space and the Return space is interrupted.

By integrating the bolts 45 between the two control discs 46 and 47 also has the upper control disk 46 when the lower control disk 46 is carried along Control disk 47 is moved in the direction of the stop 49, so that the transverse bores 14 in the piston rod 41 are connected to the return space 26 and those in the return space Compressed air located via these transverse bores and the longitudinal bore 13 in the Piston rod can relax in the direction of arrow A into the atmosphere. this has in cooperation with the blocking of the axial bores 44 in the piston 40, that now the effective area in the impact space 25 is fully acted upon again and that Housing 15 is driven down until the conical enlargement 20 is at the front of the housing strikes the conical ring surface 7 of the piston rod 41. Short before this impact, the inner surface 39 of the upper housing face 17 has the upper control disk 47 taken down, with the transverse bores 14 closed and by incorporating the bolts 45 and driving the lower ones Control disk 46 the axial bores in the piston are opened again. The described movement game then takes place again.

In FIG. 2, both the upper ring collar 12 is the piston rod Ei and the helical compression spring 36 of the embodiment of FIG. 1 are omitted. Of course, it is also possible in the embodiment of FIG Provide ring collar and the helical compression spring.

It is also possible to make piston rods 4 and 41 shorter than in the Fig. 1 and 2 shown to train. In such an embodiment, the Piston rods then only up to the upper stop 33 of the piston 24 according to FIG. 1 or up to the upper stop 49 of the upper control disk 47 of the embodiment of Fig. 2 range. The piston rod is then closed on the top and that too Housing 15, which is no longer penetrated by the piston rod in the end section 17 is. If such a short piston rod is used, the discharge takes place the used air through a transverse bore 54 in the lower anvil 7 forming Part of the piston rod 4 or 41. This cross hole can also be made with a screw 55, with which it is possible to change the cross-section of the transverse bore. It is of course conceivable to have such a throttling effect Screw or a similarly effective element in the area of the upper exhaust openings the piston rod? 4 or 41 according to FIGS. 2 to be provided.

In the context of FIGS. 3 to 5, an embodiment of a ram 56 is shown illustrated, which is lowered or at horizontal or inclined holes can be used.

This hammer drill 56 has a housing 57 in the lower End face 58 has a bore 59 which is supported by a bolt acting as an anvil 60 is penetrated, at the free end of a drilling cap 61 by means of a cross bolt 62 is attached. The drilling template is only illustrated in FIG. 3. In the 4 and 5 it has been omitted for the purpose of maintaining the clarity of the drawing been.

In the upper end side 63 of the housing 57 a bore 64 is made, Via which, according to the arrow Z, compressed air is continuously supplied to the housing in an uncontrolled manner. Furthermore, a central bore 65 is provided in this end face of the housing, into which a hollow piston rod 66 is inserted, which is suspended from a pull rope 67 and is relatively movable with respect to the housing by means of a helical compression spring 68. The helical compression spring is between an annular collar 69 of the piston rod and the The bottom of a recess 70 which is enlarged in diameter compared to the bore 65 is incorporated. The length of the piston rod 66 corresponds approximately to half the length of the housing 57.

In the housing 57 a piston 71 is longitudinally movable, but supplied in a sealing manner, which cooperates with its lower end portion 72 with the anvil 60 and the housing divided into an impact space 73 and a return space 74. The piston is over the substantial part of its length is tapered in diameter and slides only with its lower end portion 72 on the inner surface of the housing. Of the Piston has a multi-stepped, axial longitudinal bore 75 into which the piston rod 66 can immerse sealingly. In the lower length section is in the longitudinal bore an axially movable control pin 76 arranged between a conical ring collar 77 and a shoulder 78 of the piston is reciprocable.

The control pin has a frustoconical stop lug on the top 79, which are encompassed by a helical compression spring 80 will which is supported on another shoulder 81 of the piston. In the opposite end section the control pin 76 goes into a cylindrical extension which is tapered in diameter 82 over.

In the lower end section 72 of the piston 71 there is also a transverse bore 83 is provided that the annular gap between the tapered diameter part of the Piston and the housing wall with the central bore 75 connects. Furthermore is a Angle bore 84 arranged, which the return space 74 with the central longitudinal bore 75 connects.

In the impact position according to FIG. 3, according to the arrow Z Compressed air introduced via the bore 64 into the impact chamber 73 via the transverse bore 83 in the piston 71 and the central longitudinal bore 75 in the return space 74. The control pin 76 is thereby counteracted by the anvil 60 against the action of the helical compression spring 80 pressed against the shoulder æ. As a result of the different area measurements of the effective areas of the stroke space and the return space outweighs the force in the return space and consequently displaces the piston towards top dead center.

The stop lug 79 of the control pin hits just before top dead center 76 to the end face 85 of the piston rod 66, so that the control pin in the direction is shifted to the ramming object 61. The control pin now closes the transverse bore 83 between the central longitudinal bore 75 and the percussion space 73, so that the connection between the impact space and the return space 74 is interrupted will. At the same time, the return space with the hollow is via the angled bore 84 Piston rod 66 connected. The compressed air in the return space can now over the hollow piston rod according to the Flow off arrow A. At the same time, the helical compression spring 80, which controls the control pin snaps into the position shown in FIG.

Now only the effective area of the impact space 73 is filled with compressed air acted upon through the bore 64 according to the arrow Z, so that the piston 71 is downward is accelerated until it with its lower end face 86 with the anvil 60 in Contact reached.

Just before it hits the anvil, the cylindrical one also arrives Approach 82 of the control pin 76 with the kboß in contact. The control pin is thereby pushed back into position against the action of the helical compression spring 80, which is shown in FIG. 3. In this position, the stroke space 73 becomes again connected to the return space 74 and the return space from the hollow piston rod 66 separated so that the return stroke is completed. This includes the dimensioning of the effective area in the return space, i.e. the square of the inside diameter of the case, multiplied with the fourth part of Pi, in relation to the effective area of the stroke area, which is the square of the inside diameter of the housing minus the square of the Outer diameter of the piston rod multiplied by the fourth part of pi. The piston can thus rise at a pressure that corresponds to a value that is through is the weight G of the piston divided by the square of the outside diameter of the Piston rod multiplied by the fourth part of pi is given.

According to FIG. 5, the piston rod 66 is against the force of the screw compression spring 68 pulled up with the help of the support rope 67, it can be seen that the control pin 76 with its stop lug 79 on the top is no longer in contact with the piston rod can get. This has the consequence that a reversal of the control pin in the illustrated top dead center of piston 71 omitted because of the control pin the air pressure in its upper position, at which it rests against the shoulder 78 of the piston, is held. The piston then strikes the inner surface 87 of the with full force upper housing face 63 and in this way causes a possibly rammed drilling cap 61 can be released again.

It is of course possible to also use the piston rod 66 according to FIG assign a throttling to the embodiment of FIGS. 3 to 5, as is the case with the Embodiments of FIGS. 1 and 2 can optionally be provided. Further it is conceivable, the embodiment of FIGS. 3 to 5 in the application to a Ram hammer through design features to change the embodiments 1 and 2 have.

Internal tests have shown that with the full fill control according to the invention 83.3 Nm can be generated with 1 liter of air at just 5 bar. They also have Experiments have shown that in the inventive dimensioning of the effective areas of the impact and of the back-up space, very high ramming capacities can be achieved with small dimensions. For example, at 6 bar 9.5 impacts per second with an impact energy of 300 Nm can be achieved at 10 kilopond weight of the ram, with a stroke of only 0.1 m and Effective areas of 50 and 35 cm2 are required.

L e r s e i t e

Claims (16)

Claims: Resins to determine properties of the ram Soil or for obtaining soil samples, which can be displaced within a housing guided, on a hollow at least indirectly connected to the piling object Arranged piston rod, the housing in an impact and in a return space having dividing piston, whose effective side for the stroke stroke constantly is exposed to the compressed air supply in an uncontrolled manner, which means that c h n e t that the compressed air supply via the housing (15, 57) in the with a smaller Effective area provided impact space (25, 73) and the compressed air discharge from the one larger The return space (26, 74) having the active area via the hollow piston rod (4, Eil, 66) takes place, with the housing (15) or the piston (71) hitting the piling object (3, 61) acting ram, and that the impact space (25, 73) through in the piston (2Ei, 40, 71) provided channel-like recesses (27, 28 or 44 or 83) during of the entire return stroke with the return chamber (26, 74) connected in an air-conducting manner and on End of the return stroke with connection of the return space (26, 74) to the hollow piston rod (4, 141, 66) can be separated from the return space (26, 74). 2. Ram according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the square of the inner diameter (D) of the housing (15), reduced by the square of the outer diameter (d1) of the piston rod (4, 41) in which the return space (26) limiting length (11) in relation to the square of the outer diameter (d2) of the piston rod (4, 41) in the length section delimiting the impact space (25) (8), reduced by the square of the outer diameter (d1) of the piston rod (4, 41) in the length section (11) delimiting the return space (26), dimensioned approximately as 1: 2 is. 3. Ram according to claim 1 or 2, d a d u r c h g e -k e n n z e i c h n e t that the hollow piston rod (4) is directly connected to the Ranim object (3) and the housing (15) acting as a ram is guided on the piston rod (4), wherein the piston (24) through the housing (15) between two stops (31, 33) the piston rod (4) can be slid back and forth to a limited extent and via the in recesses (27, 28) provided for it when resting against the one stop (31) below Closure of the cross bores connecting the return space (26) to the piston rod (4) (14) the impact space (25) with the return space (26) and when in contact with the other Stop (33) connects the return space (26) with the piston rod (4). 4. Ram according to claim 1 or one of the following, d a d u r c h it is not indicated that the differentiation of the effective surfaces of the and return space (25 or 26) by a gradation of the outer diameter (d1 to d2) the piston rod (4) in the range of motion of the recessed according to the gradation Piston (24) is formed. 5. Ram according to claim 1 or 2, d a d u r c h g e -k e n n z e i c h n e t that the hollow piston rod (41) is connected directly to the piling object (3) and the housing (15) acting as a ram is guided on the piston rod (41), wherein the piston (40) is fixed to the piston rod (41) and on either side of each one provided by the housing (15) between two on the piston rod (41) Stops (50, 51 resp. 48, 49) entrainable control disc (46 or 47) is limited, the spacing elements penetrating through the piston (40) parallel to the piston rod (41) (45) are distanced from each other. 6. Ram according to claim 5, d a d u r c h g e k e n n -z e i c h n e t that the differentiation of the effective areas of the stroke and return space (25 or 26) by stepping the outside diameter (d1 to d2) of the piston rod (41) is effected in the range of motion of the control disks (46, 47). 7. Ram according to claim 5 or 6, d a d u r c h g e -k e n n z e i c h n e t that at the end of the impact stroke the control disc facing away from the piling object (3) (47) connecting the interior (13) of the piston rod (41) with the return space (26) Cross bores (14) and at the end of the return stroke the one facing the piling object (3) Control disk (46) with positive engagement in the piston (40) the axial through-holes Close (44) in the piston (40). 8. Ram according to claim 5 or one of the following, d a d u r c h it is noted that the between the ram object (3) and the piston (40) lying control disc (46) on the side facing the piling object (3) one dipping into a recess (53) in the housing (15) at the end of the return stroke annular extension (52) is provided. 9. Ram according to claim 3 or one of the following, d a d u r c h it is noted that between the free end of the piston rod (4, 41) and the housing face (35) incorporated an elastic return means (36) is. 10. Ram according to claim 3 or one of claims 4 to 8, d a d u r c h e k e n n n n z e i c h n e t that the piston rod is closed at the free end and the housing is not penetrated in the end section facing away from the piling object, wherein the exhaust opening (54) in the end portion adjacent to the piling object (3) is provided. 11. Ram according to claim 1, d a d u r c h g e k e n n -z e i c h n e t that the within the housing (57) and on the relative to the housing (57) movable Piston rod (66) guided piston (71) forms the ram, with the return space (74) on the one hand with the impact space (73) and on the other hand with the piston rod (66) connecting recesses (83 or 84) in the piston (71) by one between two Stops (77, 78) are axially movable and under the influence of an elastic restoring force (80) provided control pin (76) can be locked. 12. Ram according to claim 1 or 11, d adurch gek e n n z e i c h n e t that the effective area of the return space (74) is larger by such an amount is dimensioned as the effective area of the impact space (73), which is approximately the square of the Outer diameter of the piston rod (66) multiplied by the fourth part of Pi equals. 13. Ram according to claim 11 or 12, d a d u r c h g e -k e n n n z e i c h n e t that at the end of the impact stroke the control pin (76) by the piling object (60) can be displaced against the action of the elastic restoring force (80) and the Connection (BEi) between the return space (74) and the piston rod (66) blocks. 14. Ram according to claim 11 or one of the following, d a d u r c h e k e n n n n e i c h n e t that at the end of the return stroke the control pin (76) through the free end (85) of the piston rod (66) in cooperation with the elastic The restoring force (80) can be axially displaced in the direction of the rammed object (60) and the connection (83) between the impact chamber and the return chamber (73 or 74) blocks. 15. Ram according to claim 1 or 11 or one of the following, d a d u r c h e k e n n n n e i c h n e t that the piston rod (66) is attached to a suspension cable (67) hangs and between the housing (57) and the piston rod (66) an elastic Return means (68) is incorporated. 16. Ram according to claim 1 or one of the following, d a d u r ch it is not indicated that the piston rod (4, 41, 66) is provided with an adjustable throttle (e.g. 55).