FI57159C - FRAM- OCH AOTERGAOENDE SLAGANORDNING FOER JORDPERFORERING - Google Patents

Description

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Ms [B] (11> utlAooninosskaift 5'109 C (45) Patent nySnnrtty 10 C6 1733 '(51) Kv.lk. * / Lnt.CI. * E 02 D 17/14 · SUO MI — Fl N LAND (11 ) 771563 (22) Hakwnliptlvl — Ai »Sknlnf * dig 17 · 05 · 77 (FI) (23) AlkupUvt— GIMgh« ttdag 17 · 05 · 77 (41) Tulkit fulktMksI - Bltvlc offantHg lö. 11.77

National Board of Patents and Registration (44) Nihaviktipunon ja kuL) uikai * un pvm. - OQ no ftn

Patent · och regtsterstyrelaen Amekan utkgd och utl. * Krtft * n puMkanuI 29.02.ÖU

(32) (33) (31) Capture requested — Bagird prloritat 17 · 05 -76

22.10.76 USSR (SU) 2362865, 2U1653U

(71) Institut Gomogo Dela Sibirskogo Otdelenia Akademii Nauk USSR, - Krasny Prospekt 5 ^, Novosibirsk, USSR (SU) (72) Khaim Berkovich Tkach, Novosibirsk, Alexandr Dmitrievich Kostylev, Novosibirsk, Vladimir Maosovir Terin, , Alexei Danilovich Terskov, Novosibirsk, Mikhail Judkovich Bondar, Odessa, Vladimir Fedorovich Drobyazko, Odessa, USSR (SU) (7 * 0 Oy KOlster Ab (5I +) Reciprocating percussion device for drilling holes in the ground is a reciprocating percussion device for drilling holes in the ground, which is actually designed to pierce the soil by compacting it, said device being operated by a pressurized gaseous substance, and comprising a hollow cylindrical body with a pointed tip, the body containing a striker adapted to move inside, said striker forming volumes in the body an alternating anterior force chamber, the rear of the striker having a cylindrical cavity forming a rear force chamber of varying volume, said rear force chamber communicating with the front force chamber through openings in the throttle through a stepped sleeve located in a cylindrical cavity in the striker and coaxially therewith and attached to the rear end of the body, a large diameter portion of the stepped sleeve operating with the striker, having with the sleeve, the space between the large diameter portion of the stepped sleeve and the stepped sleeve forming an annular chamber.

The invention can be used particularly advantageously for piercing the soil with this combination. It may also be advantageous to use the present invention to introduce pipes into the ground when installing underground piping without a ditch excavator.

Today, soil piercing devices used under pressure with a gaseous substance, e.g. air, are known. Said devices are mostly reciprocating, i.e. they can move forward to advance in the soil, and they can also move backwards out of the soil.

A soil punching device is known which comprises a cylindrical body with a pointed front end. Said cylindrical body has a striker adapted to move back and forth inside it. At the rear of the striker there is a hollow space to which a stepped sleeve fits, which is attached to the cylindrical body by a screw connection. The sleeve has two positions: one for the forward movement of the soil punching device and the other for the backward movement. Attached to the rear end of the sleeve is a hose for delivering a gaseous substance, e.g. compressed air. The space between the outer surface of the impactor and the inner surface of the cylindrical body forms the anterior force chamber. The space at the rear end of the impactor, between its inner surfaces and the sleeve, forms the rear force chamber. The striker is provided with an opening for establishing a connection between said front and rear force chambers, in order to provide a reciprocating movement of the striker, said chambers being in communication with each other when the striker is at the front of the cylindrical body.

The soil penetrating device in question operates by means of compressed air supplied through a hose and a sleeve to the front chamber. The striker moves forward with the force of compressed air, and strikes the front end of the cylindrical body at the end of the stroke. At the same time, the compressed air passes from the rear chamber through the orifice of the striker to the front chamber.

To the extent that the area of the end of the striker subjected to air pressure in the front chamber is greater than the area of the rear surface of the striker subjected to air pressure in the rear chamber, the force applied to the striker is greater in the reverse direction than the force applied to it in the forward direction. Thus, the striker moves backwards. When the impactor opening opens below the rear edge of the sleeve, compressed air is released from the front chamber into the atmosphere. The air pressure in the front chamber drops below the air pressure in the rear chamber (which is the same as the supply pressure), the striker is made to move towards the front end of the cylindrical body, and the rotation starts again.

3 57159

To move the soil piercing device backwards, the sleeve is placed in its rearmost position by twisting it by means of an air hose attached to it.

With this sleeve setting, the compressed air travels to the rear chamber and passes periodically through the opening of the striker to the front chamber, causing the striker to reciprocate. However, in this case, the striker strikes the rear of the cylindrical body and takes the piercing device back and out of the hole pierced by the forward movement.

The soil piercing device in question suffers from the disadvantage that, in the case of a substantially long drilling, it is difficult, if not impossible, to give the core a rotational movement via an air hose. In addition, changing from one direction to another takes too much time.

Also known in the art are soil punching devices comprising a cylindrical body in which a percussion device is adapted to make a reciprocating movement within it. The rear end of the striker is concave to accommodate a sleeve attached to the cylindrical body. The space between the outer walls of the impactor and the inner walls of the cylindrical body forms the anterior force chamber.

The space between the walls of the impactor cavity and the end of the sleeve forms the rear force chamber. These chambers are connected to each other by an opening in the striker.

The sleeve has two circular projections, between which are arranged two longitudinal projections designed to limit the axial movement of the sleeve, and two recesses arranged to prevent rotational movement of the sleeve relative to the cylindrical body. The sleeve is mounted in a hole in the control element with two longitudinal grooves and a hole provided with a spring-loaded holder connected to the remote control cable. The locking element of the holder extends into the recess of the sleeve to lock the sleeve in its position. Longitudinal grooves are formed in the walls of the axial hole in the guide element. The circular and longitudinal projections allow the sleeve to have two locked positions, namely one for the forward movement of the ground piercing device and the other for its rearward movement.

✓

To move the ground piercing device forward, the sleeve is positioned so that the striker strikes the front end of the cylindrical body, and virtually simultaneously compressed air is released into the front chamber. In this mode of operation, the striker makes a reciprocating motion, striking the front end of the cylindrical body.

For the reversing movement of the piercing device, the sleeve must be placed in its second extreme position. To do this, the remote control cable of the holder is pulled by hand, whereby the locking element detaches from the recess of the sleeve. The core is then rotated, by rotating the air hose, relative to the guide element until the longitudinal projections in the sleeve are aligned with the grooves of the guide element. By the force of the compressed air contained in the rear chamber, the sleeve is moved from the front of the cylindrical body to another position. To lock the sleeve in position, it is rotated about its axis by means of an air hose, and then the locking element is actuated by disconnecting the remote control cable of the holder.

In this position, the entry of compressed air into the front chamber is promoted, and the exit of the compressed air is braked compared to the action during the forward movement of the soil piercing device, so that the striker is struck at the rear of the body as the soil piercing device moves backwards.

The soil piercing device described suffers from the disadvantage that the remote control cable may twist with the air hose or catch on another object. Another disadvantage is that twisting the air hose to effect reversal is difficult in the case of long drilling. The above-mentioned disadvantages make it difficult for the device to pierce the soil in question.

A soil piercing device is also known in the art, comprising a percussion device comprising a cylindrical body adapted to make a reciprocating movement inside the body. The rear of the striker has a cavity into which the sleeve attached to the cylindrical body fits. The space between the outer walls of the striker and the inner walls of the cylindrical body forms the anterior force chamber. The space between the walls of the impactor cavity and the end of the sleeve forms a rear force chamber. To provide reciprocating movement of the striker, said chambers are interconnected by forming an opening in the striker.

In addition, there is a sleeve which is arranged to rotate relative to the sleeve by making a groove shaped in the sleeve into which a protrusion formed in the sleeve fits. The sleeve has two rows of openings in its large diameter portion, while the sleeve has two rows of grooves in its large diameter portion, the grooves being arranged so that when the sleeve is rotated relative to the sleeve, the sleeve walls cover one row of sleeve openings and reveal another row. During the forward movement of the soil piercing device, the openings closer to the front end of the cylindrical body are closed and the openings closer to the rear end are open. Under these conditions, the compressed air enters the front chamber after the percussion openings have moved past the front edge of the sleeve, and the compressed air is removed through the open sleeve openings.

As compressed air is fed through the hose and sleeve into the rear chamber, the striker moves toward the front end of the cylindrical body, and strikes the body at the end of the forward stroke. At the same time, the compressed air passes from the rear chamber through the perforator openings to the front chamber. Due to the difference between the forces acting on the impactor from the front and rear chambers, the impactor is made to move backwards. When the percussion openings are at the sleeve openings, the compressed air exits the anterior chamber into the atmosphere.

5 57159

The backward movement of the soil piercing device is achieved by closing the supply of compressed air. With the compressed air supply closed, the sleeve is moved relative to the sleeve by spring force and rotated relative to the sleeve by a shaped groove. Later, when the supply of compressed air to the soil piercing device is restarted, the sleeve is rotated somewhat further relative to the sleeve, opening the sleeve openings closer to the front end of the cylindrical body and closing the openings closer to the rear end.

Under these conditions, the entry of compressed air into the front chamber is promoted and the exit is braked, compared to the forward movement of the action, as a result of which the striker strikes the rear of the cylindrical body.

The soil piercing device in question suffers from the disadvantage that the backward movement is caused by any interruption in the air supply, whether intentional or imperceptible, which is particularly unsuitable at the initial stage of drilling, apparently opening and closing the feed again to correct the direction of the punching device.

It is an object of the present invention to obviate the disadvantages of the soil penetrating devices described above.

It is a further object of the present invention to provide a soil penetrating device which is characterized by ease of use.

It is a further object of the present invention to provide a soil penetrating device characterized by increased operational efficiency.

Yet another object of the present invention is to provide a soil penetrating device characterized by increased reliability of backward control.

The device according to the invention is mainly characterized in that the small-diameter part of the stepped sleeve, which works with the small-diameter part of the stepped sleeve, has holes connecting the annular chamber to the source of compressed gaseous material. with a portion at its front end and coaxially therewith, the space between the ring, the inner surface of the stepped sleeve and the outer surface of the stepped sleeve forming an annular additional chamber connecting with the source of compressed gaseous material during the backward movement of the soil piercing device.

6 57159 This design arrangement allows the transition from forward to reverse by pulling the air hose and allows the transition from reverse to forward by automatically shutting off the compressed air supply.

It is desirable that the stepped sleeve and the stepped sleeve be provided with ducts arranged to connect the annular additional chamber to the atmosphere during the forward movement of the soil piercing device.

This design arrangement allows compressed air to be removed from the additional chamber, which may enter there through the clearances of the sleeve, sleeve and tire contacts, when said air is removed to the atmosphere, increasing the air pressure difference in the force chambers with a corresponding increase in holding the sleeve in its extreme forward position.

It is further desirable that the small diameter portion of the sleeve be provided with a circular post immediately behind its large diameter portion on the side facing the rear end of the cylindrical body so that the annular chamber communicates with the atmosphere during the rearward movement of the soil piercing device.

This constructional arrangement allows compressed air to be removed from the annular chamber which may enter there through the clearances of the sleeve and sleeve contact surfaces as said air enters the atmosphere, increasing the difference in force chamber air pressures corresponding to the force retaining the sleeve in its extreme position.

In addition, it is desirable that the ring be made of an elastic material in order to ensure the tightness of the annular additional chamber by forming a tight connection between the stepped sleeve and the ring by means of the latter elastic deformation.

Still further, it is desirable for the ring made of elastic material to taper on the side in contact with the stepped sleeve, the corresponding side of the stepped sleeve also being tapered, thereby providing a seal between the ring and the stepped sleeve.

It is furthermore desirable that a shouldered ring made of a rigid material, e.g. metal, is arranged between the contact surfaces of the elastic ring and the stepped sleeve in order to increase the longevity of said surfaces.

It is further desirable that, in order to simplify the structure of the soil piercing device, a liner be installed inside the stepped sleeve on its side facing the impactor so as to form ducts between the outer surface of said liner and the inner surface of the stepped sleeve, said duct connecting to the annular additional chamber atmosphere.

It is also desirable, in order to simplify the manufacture of the soil piercing device, to reduce its weight and at the same time to increase its longevity, that the lining be made of an elastic material, e.g. rubber.

The following invention will be described in detail with reference to the accompanying drawings, in which:

Figure 1 is a longitudinal sectional view of a soil piercing device embodying the present invention, with parts shown in their relative positions during forward movement of the device.

Figure 2 is a longitudinal sectional view of the same, with the parts shown in their relative positions during the rearward movement of the device.

Fig. J is a longitudinal sectional view of the same, showing an embodiment using an interposed rigid ring.

Figure 4 is a longitudinal sectional view of an embodiment of the invention in which a stepped sleeve is provided with ducts, the parts being shown in their relative positions during the forward movement of the soil piercing device.

Figure 5 is a longitudinal sectional view of the same embodiment of the invention, the parts being shown in their relative positions during the rearward movement of the soil piercing device.

- Figure 6 is a sectional view taken along line VI - VI in Figure 4 *

Figure 7 is a longitudinal sectional view of an embodiment of the invention with a liner, with the parts shown in their relative positions during forward movement of the soil piercing device.

Fig. Θ is a longitudinal sectional view of the same embodiment of the invention, the parts being shown in their relative positions during the rearward movement of the soil piercing device.

Figure 9 is a sectional view taken along line IX-IX in Figure 7.

Fig. 3 ° is a longitudinal sectional view of an embodiment of the invention, if 8 57159 ea is an elastic liner, the parts being shown in their relative positions during the forward movement of the soil piercing device.

Figure 11 is a sectional view taken along line XI-XI in Figure 10.

According to the invention, a reversible, impacting device for piercing the soil, by compacting it, comprises a hollow cylindrical body 1 (Fig. 1) with a pointed tip end designed to perform soil piercing work. The body 1 includes a striker 2 adapted to perform a reciprocating motion within it. The rear part of the striker 2 has a cylindrical cavity which forms the rear force chamber 3 · The space between the outer surface of the striker 2 and the inner surface of the body 1 forms the front force chamber 4 · The volume of the force chambers 3 Al 4 varies as the striker 2 makes the reciprocating motion. The rear chamber 3 and the front chamber 4 are connected to each other by forming openings 3 in the striker 2.

The stepped sleeve 6 is located on the hollow rear part of the striker 2 not coaxially with it, and with the body 1, respectively. The large-diameter part of the sleeve 6 fits inside the striker 2, while the small-diameter part of the sleeve is fixed to the rear end of the body 1 by a screw 7 »the hole has a hole Θ for removing compressed air into the atmosphere. The large-diameter part of the sleeve 6 has openings 9 and a circular groove 10 formed on the outside of the sleeve at the openings. The openings 9 in the sleeve 6 are designed to conduct compressed air from the rear chamber 3 to the front chamber 4 during the rearward movement of the soil piercing device. The space between the large diameter portion of the sleeve 11 and the large diameter portion of the sleeve 6 forms an annular chamber 12. A hole 13 is made in the small diameter portion of the sleeve 11 to connect the annular chamber 12 to a source of compressed air (not shown) during forward movement. The ring 14 is fixedly attached to the large diameter part of the sleeve 6 at its front end and coaxially therewith. The space between the ring 14, the inner surface of the stepped sleeve 6 and the outer surface of the stepped sleeve 11 forms an annular auxiliary chamber 13 designed to communicate with the source of compressed air during the backward movement of the soil piercing device. A spring 16 is attached between the stepped sleeve 11 and the stepped sleeve 6. The hose 17 is attached to a stepped sleeve 11 for supplying compressed air to the soil penetrating device.

The soil piercing device described above works as follows *

To move the soil piercing device forward, the stepped sleeve 11 is placed in the extreme forward position by the action of the spring 16. When the stepped sleeve is in this position, the large diameter portion of the stepped sleeve 11 closes the openings 9 in the stepped cook 6, and the front end of the stepped sleeve 11 is in contact with the ring 14. »Figure 1 shows the striker 2 in the extreme forward position during forward movement.

When the compressed air is fed through the hose 17 to the rear chamber 3, it passes through the openings 3 of the striker 2 to the front chamber 4 »

To the extent that the air pressures in the rear chamber 3 and the front chamber portion 4 are approximately equal, but the area of the end face of the striker 2 affected by the compressed air is greater than the area of the end surface of the striker 2 affected by the compressed air in the rear chamber 3. is larger than that acting in the rear chamber 3, as a result of which the striker 2 is moved towards the rear end of the body 1. When the large diameter part of the stepped sleeve 6 has covered the opening 3 in the striker 2, the supply of compressed air to the front chamber 4 is closed. When the openings 3 in the striker 2 have moved past the rear edge of the large diameter part of the stepped sleeve 6, the front chamber 4 connects to the atmosphere through the holes 8 in the screw 7 * The air pressure in the front chamber 4 coincides with atmospheric pressure and no force is applied to the striker 2 On the other hand, the rear chamber 3 is in constant contact with the compressed air with the source, and therefore the rear end of the striker 2 is affected by the air pressure. As a result of this air pressure, the striker 2 stops and begins to move forward. At the end of the forward movement, the striker 2 strikes the body 1, and at about the same time the opening 3 in the striker 2 passes the front end of the stepped sleeve 6, with compressed air passing from the rear chamber 3 through the opening 3 to the front chamber 4 * Now the striker 2 starts moving back and starts again.

As long as the soil piercing device operates in a forward-moving manner, the annular chamber 12 communicates with a source of compressed air through the hole 13 of the stepped sleeve 11, and therefore the air pressure in said annular chamber is approximately the same as the supply pressure.

The annular auxiliary chamber 13 is kept airtight by contact between the ring 14 and the stepped sleeve 11, the air pressure in said chamber being lower than in the supply. In order to form an airtight connection between the ring 14 and the stepped sleeve 11, it is desirable that the ring 14 be made of an elastic material, e.g. rubber, and that the opposite surfaces of the ring and the sleeve taper, the tight connection being ensured by elastic deformation of the ring.

The force exerted by the air pressure in the annular chamber 12 acts on the front end of the body 1 571 59 10 * This force and the action of the spring 16 keep the stepped sleeve 11 in its extreme forward position.

The backward movement of the soil piercing device is effected by pulling on the hose 17 (Fig. 2), whereby the spring 16 is compressed and the stepped sleeve 11 is moved back all the way until the end of its large diameter part abuts the inner end of the large diameter part of the stepped sleeve 6. In this position of the stepped sleeve 11, the hole 13 therein is closed by the inner wall of the small diameter part of the stepped sleeve 6. A clearance is formed between the front end of the stepped sleeve 11 and the ring 14, whereby the annular auxiliary chamber 13 comes into contact with a source of compressed air * The opening 9 in the large diameter part of the stepped sleeve 6 is open and in communication with the annular auxiliary chamber 13 *

Figure 2 shows the impactor 2 in its rearmost position during the rearward movement of the soil piercing device.

The compressed air supplied through the hose 17 to the rear chamber 3 and the annular auxiliary chamber 13 »puts pressure on the stepped sleeve 11 and holds it in place as long as the direction of action of the soil piercing device is backwards. At the same time, the compressed air contained in the rear chamber 3 acts on the rear end of the striker 2, causing the striker 2 to move towards the front end of the body 1. When the percussion openings 3 come into contact with the circular groove 10 in the large diameter part of the sleeve 6, the compressed air passes from the annular additional chamber 13 through the opening 9 and the groove 10 to the front chamber 4 ·

To the extent that the area of the end face of the striker 2 subjected to air pressure in the front chamber 4 is greater than the area of the end face of the striker subjected to air pressure in the rear chamber 3, the force applied to the striker 2 in the front chamber 4 is greater than that applied to the rear chamber 3. braking of impactor 2.

As the striker 2 moves forward, the openings 3 therein become closed by the walls of the stepped sleeve 6 and the volume of the front chamber 4 decreases, and as the air pressure there increases, the force acting on the front end of the striker still increases. As a result, the striker 2 stops and then begins to move backward. At the end of the backward stroke, the striker 2 strikes the end of the body 1, more precisely the screw 7 * As a result of the backstrokes, the device piercing the ground moves backwards, outwards from the hole. After the opening 3 in the striker 2 has passed the edge of the large diameter part of the stepped sleeve 6, the compressed air leaves the front chamber 4 into the atmosphere * The compressed air in the rear chamber 3 forces the striker 2 to move forward, and the circulation starts again.

11

Conversion of the rear cover of the soil piercing device into a forward-forward movement is achieved by closing the supply of compressed air. With the compressed slime excluded, the spring 16 moves the stepped sleeve to the front position. When the slime supply is restarted, the direction of operation of the soil piercing device is forward.

Figure 3 shows another embodiment of a soil piercing device. In this embodiment, the ring 18 is placed on the ring 14 to engage the stepped sleeve 11. The ring 18 is made of a rigid material, e.g. metal, and has an inner, circular shoulder 19 supported by a stepped sleeve 11. The principle of operation of this embodiment of the soil piercing device is analogous to that described above. The use of a rigid ring 18 increases the service life of the contact surfaces of those parts.

Figure 4 shows another embodiment of a soil piercing device. In this embodiment, the stepped sleeve 11 and the stepped sleeve 6 are provided with ducts 20 and 21, respectively, for the purpose of connecting the annular additional chamber to the atmosphere during the forward movement of the soil piercing device.

The principle of air distribution and the mode of operation of the device as it moves forward and backward remain analogous to those described above. The passages 20 and 21 allow the compressed air to escape into the atmosphere as it passes into the annular additional chamber 15 through the clearance spaces of the contact surfaces. Therefore, with the stepped sleeve 11 in its extreme forward position for the ground piercing device to move forward, the pressure in the annular auxiliary chamber 15 is the same as the atmospheric pressure in the stepped sleeve 11 of the ducts 20 communicating with the ducts 21 in the stepped sleeve 6.

To the extent that the annular chamber 12 communicates with the source of compressed air through a hole in the stepped sleeve 11, the pressure in said chamber is the same as the supply pressure. Accordingly, the pressure provided by the compressed air in the annular chamber 12 forces the stepped sleeve 11 against the ring 14.

This means increases the reliability of the operation of the soil piercing device, since whenever compressed air enters the annular auxiliary chamber 15, it is removed to the atmosphere through the ducts 20 and 21, preventing the possibility of a pressure rise in said chamber.

In order for the soil piercing device to operate in a rearward manner, the stepped sleeve 11 assumes its rearmost position, in which one of the openings of the duct 20 is closed by the non-walled part of the stepped sleeve 6, whereby the annular additional sound 15 is separated from the air

The cross-sectional view of the soil piercing device shown in Fig. 6 shows the relative positions of the hole 15 and the duct 20 in the stepped sleeve 11.

A circular groove 22 (Figures 4t 5) can be formed in the small-diameter part of the stepped sleeve 11 immediately behind the large-diameter part on the side facing the end of the body 1.

When the soil piercing device operates in a forward manner, the circular groove 22 is located in the annular chamber 12 and has no effect on the operation of the soil piercing device.

When the soil piercing device operates in a backward manner, with the stepped sleeve 11 in its rearmost position, a circular groove 22 occurs at the passage 21 in the stepped sleeve 6, whereby the annular chamber 12 connects to the atmosphere and the atmospheric pressure is maintained therein. Compressed air entering the annular chamber 12 through the clearance spaces between the opposite surfaces of the stepped sleeve 11 and the stepped sleeve 6 exits the atmosphere through a circular groove 22 and a duct 21 in the stepped sleeve 6.

This means increases the reliability of the operation of the soil piercing device during its backward cover, by means of an increased force which holds the stepped sleeve in its rearmost position.

Yet another embodiment of the invention is possible in which the stepped sleeve 11 (Figs. 7 → 9) is a collapsible structure. The liner 25 is mounted inside the stepped sleeve 11 at its end facing the striker 2 so as to form ducts 24 between the outer surface of said liner and the inner surface of said stepped sleeve, said duct connecting to the atmosphere of the annular auxiliary chamber 15. Two circular grooves 25 and 26 are provided on the outer surface of the liner 25, so that when the liner 25 is turned, the longitudinal part of the duct 24 is always in contact with its radial parts. The liner 25 is rigidly attached to the stepped sleeve 11, e.g. by screwing or pressing. Figure 9 shows the relative positions of the duct 24 and the hole 15 in the stepped sleeve 11.

When the soil piercing device operates in a forward manner, as shown in Fig. 7 *, the stepped sleeve 11 is in its extreme front position and the liner 25 fits against the ring 14, thus making the annular additional chamber 15 airtight. The compressed air which enters the annular dental chamber 15 »escapes into the atmosphere through the duct 24 and the hole 21 in the stepped sleeve 6.

When the soil piercing device operates in the manner of a backward cover (Fig. 6), the stepped sleeve 11 is in its rearmost position and one of the openings in the duct 24 is closed by the walls of the stepped sleeve 6, whereby the annular additional chamber is disconnected from the atmosphere.

The cross-sectional view of the soil piercing device in Fig. 9 shows the relative positions of the duct 24 and the hole 15 in the stepped sleeve 11. The operating principle of this embodiment of the invention is analogous to that described above. Said embodiment simplifies the manufacture of the duct »which connects the annular additional chamber 15 to the atmosphere.

Figure 10 shows another embodiment of a soil piercing device. In this embodiment, the liner 25 is made of an elastic material, e.g. rubber. The passages 24 «formed between the outer surface of the liner 25 and the inner surface of the stepped sleeve 11» connect the annular auxiliary chamber 15 to the atmosphere during the forward movement of the soil piercing device.

The cross-sectional view of the soil piercing device in Fig. 11 shows the relative positions of the duct 24 and the holes 15 in the stepped sleeve 11. The operating principle of this embodiment is analogous to that shown above.

V »-

Claims (8)

A ground and perforating impact device for soil perforation substantially designed to receive h & l into the soil by compacting the soil, said device driving a gaseous medium under pressure and comprising a hollow cylindrical body (1) with a pointed front end, the body housing a hammer (2) suitable for moving forward and backward in the same, said hammer forming in the body a variable volume front power chamber (U), the rear part of the hammer having a cylindrical cavity forming a variable volume rear power chamber (3) , wherein said rear power chamber communicates with the front power chamber via ports (5) arranged in the hammer, that the hammer locks the body as it moves forward and eats in it under the action of a compressed gaseous medium delivered into the power chambers through a step-shaped sleeve (6) located inside the cylindrical cavity of the hammer and the coaxial member therein and anchored to the rear end of the body, the portion having larger diameter of the stair-lined sleeve cooperating with the hammer has ports (9) lying so that they are thanks to a spring-loaded (16), sturdy and stair-shaped slide (11) which is coaxial with the stair-shaped sleeve, and the space between it the staircase portion of the larger diameter slide (11) and the staircase sleeve (6) form an annular chamber (12) characterized in that the smaller diameter portion of the staircase slide (11) cooperating with the smaller diameter said portion of the staircase sleeve (6) is provided with h & l (13) which connects the annulus (12) to the cold of compressed gas medium during forward & t direction of the ground-lifting device, and that a ring is fixedly mounted in the larger diameter portion of the the staircase sleeve (6) at the front end of and coaxial therewith, the space between the ring (IU) inner surface of the staircase sleeve (6) and the outer surface of the staircase slide (11) forms an annular auxiliary chamber (15) which communicates with the cold compressed gas medium during the return movement of the ground-receiving device. 2. Front and rear impact device according to claim 1, characterized in that the stair-shaped slide (11) and the stair-shaped sleeve (6) are provided with openings (20, 21) intended to be connected and to set the annular auxiliary chamber (15). ) in conjunction with the atmosphere during forward & forward movement of the ground-lifting device.