RU2601900C2 - Pneumatic hammer - Google Patents

Abstract

FIELD: tools.

SUBSTANCE: invention relates to pneumatic hammers. Hammer comprises a working tool, a casing with outlet holes, a cylindrical housing accommodating a sticker with a through axial hole, which divides the housing cavity into chambers of working and idle strokes, and a cover with an axial multichannel tube intended for compressed air inlet into the working stroke chamber. Casing envelopes the housing to form an outlet chamber. Tube is provided with outlet radial and longitudinal channels and bypass radial and longitudinal channels and tiers of radial bypass channels, squares of cross-sections of which increase towards the idle stroke chamber. Cover has a radial channel. In the housing there is a longitudinal and a radial channels.

EFFECT: as the result reduced is air consumption, increased are impacts frequency and energy.

1 cl, 2 dwg

Description

The invention relates to mining and construction, in particular to shock devices, is intended for the destruction of strong materials of artificial and natural origin.

A pneumatic impact device is known (see, for example, AS 514092, Mcl ² E21C 3/24, B25D 9/26, 1976), comprising a housing, longitudinal and radial channels, working and idle chambers , drummer, air distribution device, and the housing is made with an additional longitudinal channel communicating with the chambers of working and idle by means of radial channels located one from the other at a distance not greater than double the length of the striker.

Pneumatic device of shock action on.with. 514092 has the following disadvantages: the presence of an air distribution device of any type that is not consistent with the movement of the striker, which leads to a delay or advancing the transfer of an element of the air distribution device, does not provide timely air inlet into the working chambers; the presence of an additional longitudinal channel with radial exits-inlets located one above the other at a distance not greater than double the length of the striker, which leads to the transfer of part of the air from the working chamber to the idle chamber before it is released into the atmosphere, usually with a low exhaust pressure air, which when released from both working chambers does not provide tangible savings in air taken from the network.

Also known is a pneumatic hammer (see, for example, A.S. 1158341, IPC B25D 9/26, 1985), comprising a housing with exhaust channels, a drummer housed therein, dividing the housing cavity into chambers for working and idling, periodically communicating between each other using the bypass channel, made in one of the elements of the hammer, and the working tool, while the output of the displacement channel is located on the surface of either the housing or the striker in the area between the outlet channels and the end face of the striker at the moment of contact of the latter with the working tool.

Technical solution for A.S. 1158341 has the following disadvantages. In the idle chamber operating cycle, only part of the air of the working chamber is reused before it is released into the atmosphere. This causes a sharp air bypass in the cycle of the idling chamber to increase the back pressure immediately before the impactor strikes the shank of the working tool, which causes a sharp braking of the impactor and a decrease in its impact speed and, as a consequence, a decrease in the frequency and energy of the impact.

The presence of intake channels of the air supply to the idle chamber, made in the wall of the housing, leads to an increase in the diameter of the housing and its mass. The implementation of the exhaust channels in the housing will require an air baffle ring to extinguish the flow of exhaust exhaust air, which leads to an increase in hammer parts and mass.

Also known is a pneumatic hammer (see, for example, the USSR AS 1061982, MKL. B25D 9/04, E21C 3/24, 1983), containing a cylindrical body, a drummer placed in it with a through axial hole separating the body cavity on the working and idling chambers, a cover with an axial multichannel tube, which serves for the intake of compressed air into the chambers, a working tool and a system of exhaust throttles periodically communicating the chambers with the atmosphere, and the exhaust throttle system is made in the tube and cover.

Technical solution for A.S. 1061982 adopted as a prototype, as having the greatest number of essential features.

The prototype (A.S. 1061982) has the following disadvantage. In the working cycle of the working and idle chambers, air is admitted from the network into each of the chambers and exhaust air is also discharged from each chamber, which leads to a significant non-productive overspending of air from the network when each chamber communicates with the atmosphere, which reduces the efficiency of the working cycle and hammer in general.

The noted disadvantage of the prototype is eliminated in whole or in part if air is taken from the network only by the working chamber with subsequent controlled bypass of air into the idling chamber from which to discharge into the atmosphere, for which the bypass channel must be made with tiers of radial holes, through which the working and idling periodically communicate with each other when the lateral surface of the striker is blocked by the exhaust channel from the idle chamber. Thus, the working chamber with the atmosphere is not communicated.

The technical problem for the inventive pneumatic hammer provides for dosing the amount of bypassed air between the chambers to ensure a decrease in back pressure in the idle chamber during the working stroke of the hammer. This ensures the amplification of the pulse of the air pressure forces for acceleration of the striker during the working stroke, the exclusion of the unproductive part of the air flow from the side of the working stroke chamber, an increase in the impact speed, as well as the frequency and energy of the impact. At the same time, the stability of the flow of exhaust air from the working chamber to the idling chamber is maintained, the reliability of starting the pneumatic hammer is ensured.

The essence of the proposed technical solution for a pneumatic hammer is as follows.

A pneumatic hammer containing a cylindrical body, a drummer placed in it with a through axial hole, dividing the body cavity into working and idle chambers, a cover with an axial multichannel tube serving to supply compressed air to the working chamber, a working tool and an exhaust system, periodically communicating the idle chamber with the atmosphere, made in the tube and the lid, and the tube is equipped with a bypass channel with tiers of radial holes, forming a variable cross-sectional area, increased walking towards the idle chamber with restriction by the end face of the striker on the side of the working chamber, and communicating between the working and idle chambers when the length of the striker along the cutting ends is longer than the length that cuts off the edge of the outlet channel of the tube from the side of the striker facing the working chamber, and the length from the cutting edge of the outlet channel of the tube from the side of the end of the striker facing the idle chamber is less than the length to the cutting edge of the exhaust channel from the side of the end of the striker facing Yeru stroke, and is formed along the length of not greater than the length of the discharge passage in the tube bounded impactor cutoff edge end of the working stroke chamber.

The execution of the pneumatic hammer is illustrated by a partial longitudinal section shown in Fig. 1, and a fragment of the bypass channels in tiers with increasing passage sections towards the idle chamber in Fig. 2.

The pneumatic hammer contains a housing 1, a hammer 2, forming an idle chamber 3 and a working chamber 4 in the cavity of the housing 1, a working tool 5 with a device for holding it, for example, an end spring 6, a handle 7 with any known type of air distribution, a casing 8 s radial outlet openings 9 and covering the housing 1 and the housing 10 of the handle 7, forming the exhaust chamber 11, the cover 12, pressed by the handle 7 to the end of the housing 1 from the side of the chamber 4 of the stroke. In the cover 12, an inlet channel 13 is made into the working chamber 4 and, coaxially with the longitudinal axis of the housing 1, a multichannel tube 14 is sealed and fixed relative to the cover 12. An annular air pre-chamber 15 is formed between the handle 7 and the cover 12, which enters through the channel 16 in the handle 7. In the multi-channel tube 14, a radial channel 17 is made with a continuation into the longitudinal channel 18 with exit through the radial channel 19 in the cover 12, then the longitudinal channel 20 in the housing 1 into the radial exhaust channel 21 and the exhaust chamber 11. Depending on Proposition impactor 2 through these outlet channels 17, 18, 19, 20, 21 and exhaust openings 9 in the housing wall 8, the chamber 3 is idling periodically communicates with the atmosphere. To bypass the air from the working chamber 4 to the idling chamber 3, a radial bypass channel 22 is made on the lateral surface of the multichannel tube 14 and continues into the longitudinal channel 23 with a constant outlet 24 directly to the idling chamber 3. On the section of the longitudinal channel 23, radial bypass channels 25 are made in tiers, with access to the idle chamber 4, which periodically inform, depending on the position of the hammer 2, the working chamber 4 and the idle chamber 3 between themselves. The working chamber 4 and the idle chamber 3 communicate with each other only when the radial exhaust channel 17 is blocked by the striker 2. The working chamber 4 does not communicate directly with the atmosphere.

Air hammer works as follows.

In the initial position (see drawing), the hammer with the working tool 5 abuts against the medium to be processed, and the hammer 2 is in contact with the working tool 5, which is held relative to the housing 1 by an annular spring 6.

After turning on the hammer, compressed air from the network through the channel 16 in the handle 7 enters the pre-chamber 15, from where the air enters the working chamber 4 through the inlet channel 13 in the cover 12 and, at the same time, through the radial inlet channel and its continuation in the form of a longitudinal channel 23, air enters chamber 3 idling.

The air pressure in the chamber 4 of the working stroke is set to be smaller than the network pressure, but sufficient to fill the chamber 3 of idling air with the same pressure, which is ensured by the bore of the channels 22, 23, 24 and 25 of the bypass air from the chamber 4 of the working stroke into the chamber 3 of idling .

The air pressure in the idle chamber 3 is calculated and sufficient in magnitude to generate a pressure impulse from the side of the idle chamber 3 to overcome the shock of the counterpressure air from the side of the working chamber 4, which has the functions of a flow chamber with lower air pressure than the idle chamber 3 stroke, possessing the functions of a non-flow chamber with increasing air pressure.

Under the influence of an impulse of air pressure forces from the side of the idle chamber 3, the striker 2 starts its movement towards the cover 12, making idle.

Moving toward the cover 12, the firing pin 2 closes the bypass channels 22 and 25 and the air bypass from the working chamber 4 to the idle chamber 3 is stopped, as a result of which the compressed air cut off in it and the air entering through the inlet channel 13 from the prechamber will begin in the chamber 4 fifteen.

With further movement, the hammer 2 will open the outlet radial channel 17 in the wall of the multi-channel tube 14 and the exhaust air is discharged from the idle chamber 3 through the outlet longitudinal channel 18 and the radial channel 19 and then through the outlet channels 20 and 21 into the chamber 11, then through the outlet channels 9 in the casing 8 to the atmosphere, as a result of which the air pressure in the idle chamber 3 is set close to the atmospheric air pressure.

Overcoming the backpressure of the air from the side of the chamber 4 of the working stroke from the compression of the air available and coming through the inlet channel 13 from the pre-chamber 15, the hammer 2, having exhausted the idle pulse and having reached the design position, will stop. Immediately after stopping under the influence of air pressure from the side of the chamber 4 of the working stroke, the striker 2 will begin accelerated movement towards the working tool 5, making a working stroke.

Moving towards the working tool 5, the firing pin 2 sequentially blocks the bypass channels 22 and 25, then the exhaust channel 17 and opens the bypass channels 22 and 25.

The movement of the striker 2 leads to an increase in the volume of the chamber 4 of the working stroke, the air pressure in which does not significantly decrease, since with a decrease in air pressure in the chamber 4 of the working stroke, its flow from the pre-chamber 15 through the channel 13 increases, which allows the calculated air pressure, and therefore, provide the drummer 3 with the necessary pulse size of the air pressure force during the working stroke.

Moving, the hammer 2 will open the bypass channels 22 and 25, as a result of which the air from the chamber 4 of the working stroke enters the channel 23 and into the volume of the chamber 3 idling. The air pressure in the idle chamber 3 will be insignificant, since the striker 2 only compresses the air cut off in the chamber, which causes a back pressure that does not significantly affect the braking of the striker 2.

Overcoming the force of counter-pressure of compressed air and again received through the channels 13, 22, 25 and 23 into the idle chamber 3, the striker 2 strikes the working tool 5, as a result of which the kinetic energy of the shock acquired by it during the period of the working stroke is transmitted to it.

The subsequent idling will be carried out due to the impulse of the air pressure force from the side of the idle chamber 3 and the impulse of the rebound of the striker 2 from the working tool 5. Next, the shock pulse from the working tool 5 will be transmitted to the medium being processed, and the working cycle will be repeated.

Claims (1)

A pneumatic hammer containing a working tool, a casing with outlet openings, a cylindrical body, a drummer with a through axial hole located therein, dividing the body cavity into working and idle chambers, and a cover containing an axial multichannel tube and designed to let compressed air into the working chamber stroke, while the casing covers the housing with the formation of the exhaust chamber, characterized in that the tube is made with the outlet radial and longitudinal channels and bypass radial and longitudinal channels and tiers of radial bypass channels, the cross-sectional areas of which increase towards the idle chamber, while the lid has a radial channel, longitudinal and radial channels are made in the housing, and the hammer is capable of sequentially closing the radial bypass channel, tiers of the radial bypass channels and radial outlet channel and the opening of the radial bypass channel and the tiers of the radial bypass channels of the tube during its working stroke, and the closure of the radial bypass channel ala, tiers of radial bypass channels and opening of the radial bypass channel of the tube when it is idling, and when opening the radial bypass channel and tiers of the radial bypass channels of the tube, the working and idle chambers are provided through the radial bypass channel, tiers of the radial bypass channels and the longitudinal bypass channel in the tube, and when the radial outlet channel of the tube is opened, the idle chamber communicates with the atmosphere through the radial the outlet channel and the longitudinal outlet channel in the tube, the radial channel in the cover, the longitudinal and radial channels in the housing, the outlet chamber and the outlet openings in the casing.

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