RU2105881C1 - Impact-action device - Google Patents

Abstract

FIELD: mining and construction industries. SUBSTANCE: this is intended for making holes in ground, crushing rock matter, driving rod members into ground, compaction of ground, and other operations. Enhanced reliability of device is achieved due to improved design of shut-off valve. Device has body, striker, direct stroke chamber, reverse stroke chamber, shut-off valve made in the form of resilient ring installed in annular groove in outer surface of striker for possible interaction with inner surface of body which has forward circular protrusion and reverse stroke limiter. Compression air is delivered to direct stroke chamber via passage and to reverse stroke chamber also via passage. Initial closing of reverse stroke chamber takes place at moment when resilient ring touches forward circular protrusion. At this, increasing pressure in reverse stroke chamber comes to bear on inner surface of resilient ring and stretches it. At end of reverse stroke, resilient ring comes over reverse stroke limiter (shoulder), turns in groove and, under action of elastic force and air pressure exerted on outer surface of resilient ring, contracts quickly. Discharge of compressed air from reverse stroke chamber is performed. At end of direct stroke, impact is executed, resilient ring comes over forward circular protrusion, reverse stroke chamber is closed, and cycle is repeated. EFFECT: higher efficiency. 14 cl, 8 dwg

Description

 The device relates to mining and construction equipment and can be used for driving wells in the ground during trenchless laying of underground utilities, for driving pipes, destroying rocks, tamping the soil, etc.

 Known pneumatic shock device for the formation of wells in the soil / 1 /. It contains a housing, a hammer, an inlet and outlet, an air distribution pipe, and forward and reverse chambers.

 The disadvantages of the device are the resistance to the stroke of the striker on the side of the reverse chamber, which closes after the compressed air is exhausted into the atmosphere and the pressure rises due to compression. This slows down the firing pin and reduces the impact energy.

 The closest technical solution is a pneumatic percussion mechanism / 2 /, which contains a housing with inlet and outlet openings, mounted with the possibility of movement, a striker, forward and reverse cameras, a channel in the striker for communication of forward and reverse cameras, a shut-off valve-tip. The shut-off valve is opened manually by pressing the body on the valve-tip. In this case, the reverse chamber communicates with the atmosphere, and compressed air is exhausted.

 The disadvantages of the pneumatic impact mechanism is the slow and at different speeds the opening of the exhaust opening, which leads to a decrease in impact energy and frequency of impacts, as well as their instability. In addition, the pneumatic impact mechanism is unreliable in operation, since the entire impact is transmitted through the shutoff valve.

 The technical problem solved in the present invention is to increase the impact energy while increasing the reliability of the device.

 The problem is solved in that in the percussion device, comprising a housing with inlet and exhaust openings, mounted in the housing with the ability to move the firing pin, forward and reverse cameras, a channel in the drummer for communicating the forward and reverse cameras, a shut-off valve, on the outer surface the striker is made an annular groove, on the inner surface of the housing there is a front annular protrusion and a backstop, and the shut-off valve is made in the form of an elastic ring mounted in an annular ring Navka drummer with the ability to interact with the inner surface of the body.

 This embodiment of the impact device allows to increase the impact energy, reliability and stability. The implementation of the shut-off valve in the form of an elastic ring installed in the annular groove of the striker with the possibility of interaction with the annular protrusion and the backstop limiter provides the most rapid and complete opening of the exhaust hole, the message of the backstroke chamber with the atmosphere during the complete stroke of the striker, thereby eliminating resistance forward stroke of the striker from the backward camera side and the impact energy is maximized. In addition, this embodiment of the device provides a constant reverse stroke of the striker, due to this, the stability of energy and frequency of impacts protects the device from hitting the back of the case, increases the reliability of the device.

 The implementation of the striker backstop in the form of a shoulder on the inner surface of the housing allows you to rotate the elastic ring in the annular groove, thereby ensuring reliable operation of the shut-off valve and opening the exhaust outlet.

 The implementation of the striker backstop in the form of recesses or through holes allows you to start the exhaust before the shut-off valve is activated, thereby reducing the pressure holding the shut-off valve or elastic ring on the exhaust hole, and it is compressed.

 If grooves or holes are made in the collar, as a striker backstop, then the rotation of the elastic ring in the annular groove and the exhaust will begin simultaneously. There will be a more rapid decrease in pressure, which holds the elastic ring in the extended state. This ensures a more reliable actuation of the shutoff valve and the opening of the exhaust outlet.

 The implementation of the surface of the front annular protrusion of the spherical increases the reliability of locking the reverse chamber due to the smooth stretching of the elastic ring of the shut-off valve.

 The implementation of the surface of the front annular protrusion of the conical, in addition to reliable locking of the reverse chamber, improves the manufacturability of the product.

 If the elastic ring is rectangular in cross section, then when the front outer edge of the ring is touched against the front annular protrusion made on the inner surface of the housing, the elastic ring rotates in the annular groove under the influence of increasing pressure in the backward chamber, thereby ensuring reliable locking of the backward chamber . When the back outer edge of the rectangular elastic ring is touched against the backstop, the ring will turn in the annular groove in the opposite direction, thereby reducing the pressure that holds the ring in the extended state, compressing the ring and reliable exhaust.

 If the elastic ring in the cross section is made round, then its local wear will be reduced due to the possibility of its rotation in the groove and overlapping on the inner surface of the body during the reverse stroke of the hammer.

 If the percussion device is provided with a guiding element for the striker, the reliability of locking the return chamber at the forward position of the striker is increased by ensuring alignment of the elastic ring and the front annular protrusion.

 The implementation of the guide element in the form of a through rod, mounted in the housing, allows several times to reduce the length of the impact device, reduce the mass of the housing and thereby reduce shock loads on the housing.

 The implementation of the guide element in the form of an annular series of protrusions on the inner surface of the housing allows to simplify the design of the impact device by combining the functions of the guide element and at the same time a backstop.

 The implementation of the guide element in the form of an annular row of protrusions on the outer surface of the striker increases the manufacturability of the product by simply making grooves on the outer cylindrical surface of the striker.

 The implementation of the channel for communication forward and reverse in the rod reduces the number of stress concentrates in the hammer and increases its strength.

 The supply of the housing of the impact device of the anvil with an annular protrusion and a backstop on its inner surface reduces the impact of shock loads on the housing, increases the reliability of operation, and simplifies the design.

 In FIG. 1 shows a longitudinal section of a percussion device with a rectangular cross section of an elastic ring and with a striker backstop in the form of a shoulder; in FIG. 2 is a longitudinal section of a percussion device with a spherical surface of the front annular protrusion; in FIG. 3 is a longitudinal section of a percussion device with a conical surface of the front annular protrusion and with a striker backstop in the form of recesses or through holes on the inner cylindrical surface of the body; in FIG. 4 is a longitudinal section of a percussion device with a striker backstop in the form of a shoulder with grooves or holes; in FIG. 5 is a longitudinal section through a percussion device with a circular cross section of an elastic ring; in FIG. 6 is a longitudinal section of a percussion device with a guiding element for the hammer in the form of a through rod with a channel fixed in the housing; in FIG. 7 is a longitudinal section of a percussion device with a guiding element for the striker in the form of an annular row of protrusions made on the inner surface of the body; in FIG. 8 is a longitudinal section of a percussion device with a guiding element for the striker in the form of an annular row of protrusions on the outer surface of the striker.

 The shock device (Fig. 1) comprises a housing 1, a hammer 2, a forward chamber 3, a reverse chamber 4, a shut-off valve 5. In the housing 1, intake channels 6 and 7 are made. On the inner surface of the housing 1, a front annular protrusion 8 and a backstop limiter 9 are made. Between the annular protrusion 8 and the backstop limiter 9 there is a cylindrical surface 10 of the backstop chamber 4. A through channel 11 is made in the drummer. An annular groove 12 is made on the outer surface of the drummer 2 , a shutoff valve 5, made in the form of an elastic ring having an outer 13 and an inner 14 surface, and installed in the annular groove 12 with a gap of 15.

 In the impact device, the surface of the front annular protrusion 8 can be made spherical (Fig. 2) or conical (Fig. 3-8).

 The backstop 9 can be made in the form of a shoulder (Fig. 1, 2, 4, 6, 7, 8), in the form of recesses 16 or through holes 17 on the inner cylindrical surface of the housing 1 (Fig. 3, 5).

 In the shoulder can be made grooves 18 or holes 19 (Fig. 4, 6, 7, 8).

 The shutoff valve 5 can be made in the form of an elastic ring of rectangular cross-section (Fig. 1, 2, 3, 4, 6, 7, 8) or circular cross-section (Fig. 5).

 The impact device may be provided with a guide element 20 for the hammer, made in the form of a through rod fixed in the housing 1 (Fig. 6), made on the inner surface of the housing 1 in the form of an annular row of protrusions (Fig. 7), made on the outer surface of the hammer 2 in the form of an annular row of protrusions (Fig. 8).

 The channel 11 for communication cameras forward and reverse can be performed in a through rod 20.

 The front of the housing 1 can be made in the form of a separate part - anvil 21, on the inner surface of which there is a front annular protrusion 8, a backstop 9 and a cylindrical surface between them (Fig. 6, 8).

 The impact device operates as follows (Fig. 1).

 Compressed air through channel 6 enters the forward chamber 3. Under the influence of compressed air pressure, the hammer 2 moves to the lowest position (according to the drawing) and abuts against the front end of the housing 1. In this case, the elastic ring 5 comes into contact with the front ring ledge 8 - 4 reverse camera is locked.

 Through channel 11, compressed air enters the return chamber 4, and the pressure rises in it. Under the action of pressure on the inner surface 14, the elastic ring 5 stretches and is pressed by its outer surface 13 to the cylindrical surface 10. At the same time, the elastic ring 5 is pressed by pressure to the upper (according to the drawing) side surface of the groove 12. Under the action of pressure in the return chamber 4, due to the difference in area, the drummer 2 moves to the upper (according to the drawing) position. When the elastic ring 5 touches the backstop 9, made in the form of a collar, the elastic ring 5 rotates in the groove 12. In this case, the outer surface 13 is forced to move away from the cylindrical surface 10. Compressed air acts on the outer surface 13, thereby equalizing its tensile force on the inner surface 14. In addition, when meeting with the shoulder 9, the elastic ring 5 moves on the groove 12 in the axial direction. According to the gap between the ring 5 and the upper (according to the drawing) side surface of the groove 12, compressed air escapes from under the inner surface 14 of the ring 5. Ring 5 under the action of elastic forces and pressure on the outer surface 13 is rapidly compressed and opens the outlet for compressed air from the chamber reverse 4. Under the influence of pressure in the forward chamber 3, the hammer 2, not encountering resistance from the side of the reverse chamber 4, accelerates downward and strikes the front end of the housing 1. In the lowermost position of the hammer 2 rugoe ring 5 comes into contact with the front annular projection 8 comes locking flyback chamber 4. The cycle repeats itself.

 When performing the backstop 9 of the striker 2 in the form of recesses 16 or through holes 17 (Fig. 3), the exhaust differs from that described above. When the elastic ring 5 exits into the recesses 16 or holes 17, the exhaust starts, and the pressure decreases in the groove 12, where the ring 5 is located. Under the action of elastic forces, the ring 5 is compressed and lowered into the groove 12 before the start of the next cycle.

 The use of an elastic ring as a shut-off valve, deformable in the radial direction, in the presence of a front annular protrusion and a backstop limiter provides quick opening at the end of the backstop of the annular hole for the release of compressed air from the backstop, message backstroke chamber with the atmosphere during forward stroke , practically prior to impact, reliable locking of the reverse chamber in the extreme forward position of the striker and during its reverse motion, a constant location for opening the reverse chamber about the stroke, determined by the location of the backstop. This provides high impact energy, reliability and stability of the impact device, the constancy of energy and frequency of impacts.

Claims (14)

 1. The percussion device, comprising a housing with inlet and exhaust openings, mounted in the housing with the possibility of moving the firing pin, forward and reverse cameras, a channel in the firing pin for communicating the forward and machining chambers, a shut-off valve, characterized in that on the outer surface of the firing pin an annular groove is made, a front annular protrusion and a backstop are made on the inner surface of the housing, and the shut-off valve is made in the form of a stop ring installed in the annular groove of the hammer to cooperate with the inner surface of the housing.  2. The device according to claim 1, characterized in that the striker backstop is made in the form of a shoulder on the inner surface of the body.  3. The device according to claim 1, characterized in that the striker backstop is made in the form of recesses or through holes on the inner cylindrical surface of the housing.  4. The device according to claim 2, characterized in that the groove is made of grooves or holes.  5. The device according to claim 1, characterized in that the surface of the front annular protrusion is made spherical.  6. The device according to claim 1, characterized in that the surface of the front annular protrusion is made conical.  7. The device according to claim 1, characterized in that the elastic ring is rectangular in cross section.  8. The device according to p. 1, characterized in that in cross section the elastic ring is made round.  9. The device according to claim 1, characterized in that it is provided with a guide element for the drummer.  10. The device according to claim 9, characterized in that the guide element is made in the form of a through rod fixed in the housing.  11. The device according to claim 9, characterized in that the guide element is made on the inner surface of the housing in the form of an annular row of protrusions.  12. The device according to claim 9, characterized in that the guide element is made on the outer surface of the striker in the form of an annular row of protrusions.  13. The device according to claims 1 and 10, characterized in that the channel for communicating the forward and reverse cameras is made in the rod.  14. The device according to claim 1, characterized in that the housing is equipped with an anvil, on the inner surface of which an annular protrusion and a backstop limiter are made.

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