RU2583571C1 - Pneumatic hammer with internal arrangement of channel in striker - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates to pneumatic percussion machines. Pneumatic hammer comprises a cylindrical body, a working tool, a partition with an axial hole in which tube is installed and secured with a longitudinal outlet port and radial discharge port, and a drummer with a through axial channel for passage of said tube. Striker divides cylindrical body into working stroke chamber on side of partition and idle stroke chamber from side of working tool. In cylindrical body on side of idle stroke chamber there is a groove. In body of striker there is a bypass channel of round section in form of a direct channel, inclined to axis of striker, or crank channel. Bypass channel is made with a constantly open output in end of striker on side of working stroke chamber and radial output in its side surface in said groove idle stroke chamber to communicate chambers of working and idle strokes with each other.

EFFECT: reduced consumption of compressed air.

1 cl, 2 dwg

Description

The invention relates to pneumatic impact machines and can be used in construction, mining and mechanical engineering.

Known pneumatic hammer (ed. St. USSR No. 1158341, IPC B25D 9/26, 1985) containing a housing with inlet and outlet channels, a drummer located therein, dividing the body cavity into the working and idle chambers, periodically communicating with each other using the displacement channel, made in one of the elements of the hammer, and a working tool, and 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 of the striker at the moment of contact of the latter with the working tool. Also, the input of the displacement channel when performing the latter in the drummer is located on the inner cylindrical surface from the side of the idle chamber. Also, the displacement channel is a blind groove on the cylindrical surface of the drummer with access to its end from the side of the idle chamber.

This pneumatic hammer has the disadvantages of:

- the displacement channel on the surface of either the housing or the striker in the area between the inlet channels and the end of the striker at the moment of contact of the latter with the working tool excludes the growth of back pressure in the idle chamber, but at the same time reduces the initial momentum of air pressure from the side of the idle chamber, which increases the idle time stroke, and therefore reduces the frequency of impacts and impact power of the hammer as a whole;

- the outlet of the displacement channel is located on the surface of either the housing or the striker in the area between the exhaust channel and the end of the striker at the moment of contact of the latter with the working tool, which causes, at the end of the stroke and the beginning of the idle stroke of the striker, the idle chamber communication with the atmosphere and unproductive air flow from the network, and therefore increases the total air flow and reduces the economy of the hammer as a whole.

Also known is a pneumatic hammer (ed. St. USSR No. 1172692, IPC B25D 9/04, 1986, prototype), comprising a cylindrical body with a handle, an exhaust channel, a flow chamber constantly communicating with the air supply channel with a compressed air network, a striker dividing the body cavity on the working chamber, constantly in communication with the flow chamber and alternately with the atmosphere, and the idling chamber, alternating in communication with the atmosphere, and a throttle, and in the case between the working chamber and the flow chamber there is a partition with a central hole with a rod installed and fixed in the hole coaxially to the body of the housing, in which additional air supply channels are made to the idle chamber, constantly communicating with the flow chamber, and an exhaust channel, at one of the ends of which a throttle is installed, and the other is connected to the atmosphere, the hammer is installed coaxial to the rod with the ability to move along it.

This pneumatic hammer is adopted as a prototype, as having the greatest number of essential features common with the claimed.

The prototype has the following disadvantages:

- in the working cycle of the working and idling chambers, air is admitted into each of the chambers and exhaust air is also discharged from each chamber, which leads to a significant unproductive air flow from the network when each chamber communicates with the atmosphere, which reduces the efficiency of the working cycle and hammer generally;

- the inlet channel to the idle chamber and the exhaust channel from the working and idle chambers are made in one tube of the air supply and exhaust air exhaust, which leads to an increase in the transverse dimensions of the tube;

- the exhaust channel in the tube for the chambers of working and idling causes an increase in the transverse dimensions of the channel to ensure the exhaust of exhaust air during one cycle, which requires an additional increase in the transverse dimensions of the tube, hammer and mass of the hammer as a whole.

The noted disadvantages are eliminated in whole or in part, if the air inlet into the idle chamber is carried out by bypassing the air from the working chamber, and the exhaust air is discharged only from the idle chamber.

The technical problem for the inventive pneumatic hammer involves reducing air flow, reducing the transverse dimensions of the tube, impactor and hammer body by periodically releasing exhaust air from the idle chamber by performing an exhaust channel in the tube and a bypass channel with a cut-off edge on the side surface of the hammer.

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

The pneumatic hammer comprises a cylindrical body, a working tool held relative to the cylindrical body, a handle with an intake device and a body with air supply and exhaust channels, a baffle with an inlet throttle and an axial hole with a tube installed and fixed in it, formed by a baffle, a cylindrical body and a handle body an outlet chamber with an outlet formed by a handle body and a baffle, a flow chamber communicated by an air supply channel with compressed air network, a longitudinal exhaust channel in the tube with a radial exit to its side surface, a drummer with a through axial channel for passing the tube, dividing the cavity of the cylindrical body into the working chamber from the partition side, constantly in communication with the flow chamber through the inlet throttle in the partition, and the idle chamber from the side of the working tool, periodically communicating by means of a radial and longitudinal exhaust channels in the tube and the partition with access to the annular exhaust chamber and and through an outlet in the handle housing into an atmospheric chamber formed by the handle housing and an air baffle ring, the cylindrical body on the side of the idle chamber having a recess, and a round cross-section channel with a constant exit to the end face of the striker on the side of the working chamber and a radial exit to the side surface of the striker and to the undercut of the idle chamber, made in the form of either a direct channel or a cranked channel, periodically informing the working chamber th idle and moves between a closed position in radial discharge passage in the tube from the end face of the impactor idling chamber.

The design of a pneumatic hammer with a bypass channel on the side surface of the hammer is illustrated by drawings of its partial section: in FIG. 1 - implementation of the bypass channel in the form of a direct channel of circular cross section, inclined to the axis of the drummer with a radial exit to its side surface; in FIG. 2 - execution in the form of a cranked circular section with a radial exit to the side surface of the striker.

The designations of the main elements of the hammer in all the drawings are the same.

The pneumatic hammer contains a cylindrical housing 1 with a coaxial undercut 2, a working tool 3 held by a spring 4 relative to the housing 1, a baffle 5 with an inlet choke 6, an outlet channel 7, in a tube 8 with a longitudinal outlet channel 9 and a lateral outlet channel 10, which constantly communicates channels 7 and 9, the radial channel 11 on the side surface of the tube 8, constantly in communication with the longitudinal exhaust channel 9, the hammer 12 with an axial through channel 13 and the bypass channel 14, made in the body of the hammer 12 in the form of either direct to anal (see Fig. 1) of circular cross section, inclined to the axis of the drummer 12 with a radial exit to its lateral surface and to the undercut 2 of the idle chamber 15 with a constantly open exit to its end from the side of the 16th stroke chamber or the crankshaft channel (see Fig. 2) with a radial exit to the side surface of the striker 12 and to the recess 2 of the idle chamber 15 with a constantly open exit to its end from the side of the 16 stroke chamber.

With the contact position of the hammer 12 and the working tool 3, the idle chamber 15 with a recess 2 on the side of the working tool 3 and the working chamber 16 on the side of the partition 5 by the bypass channel 14 made in the body of the hammer 12 in the form of either a direct channel (see. 1) a circular cross-section inclined to the axis of the striker 12 with a radial exit to its side surface and into the undercut 2 of the idle chamber 15 with a constantly open exit to its end from the side of the 16-stroke chamber or of the cranked channel (see Fig. 2) radial output n side surface and the striker 12 in the recess 2 cameras 15 idling with the permanently open outlet at its end face on the side of the chamber 16 of the working stroke are communicated with each other.

The handle 17 by means of a threaded connection on its body 18 and the cylindrical body 1 densely presses the partition 5 to the end of the cylindrical body 1 from the side of the chamber 16 of the stroke. The handle 17 and its housing 18 contain an inlet channel 19, an exhaust channel 20 in the wall of the housing 18 and a flow chamber 21 of the network air.

Between the housing 18 of the handle 17 and the cylindrical housing 1, an annular exhaust chamber 22 is formed, which, through a channel 20 in the housing 18, is in communication with the atmospheric chamber 23 formed by the housing 18 and a baffle ring 24 detachable with it. The housing 18 of the handle 17 is fixed relative to the cylindrical housing 1 by a latch 25, held relative to the cylindrical body 1 and the housing 18 of the handle 17 by an annular casing 26.

Air hammer works as follows.

After turning on the network air supply device (not shown in the drawing and can be any known by design), the air enters through the inlet channel 19 of the handle 17 into the flow chamber 21, from where it passes through the inlet choke 6 in the baffle 5 into the working chamber 16 in the cylindrical housing 1 .

With the position of the pneumatic hammer shown in FIG. 1, air from the chamber 16 of the working stroke through the bypass channel 14, made in the body of the drummer 12 in the form of either a direct channel (see Fig. 1), or a cranked channel (see Fig. 2) with a radial exit to its side surface enters the idle chamber 15 formed by a recess 2 in the cylindrical housing 1. At the moment of the idle chamber 15 and the working chamber 16, the camera functions change: the idling chamber 15 acquires the functions of a closed chamber, the working chamber 16 - the functions of a flow chamber. Due to the above, in the idle chamber 15, the air pressure rises and becomes larger than the pressure in the working chamber 16. Under the influence of air pressure on the end face of the striker 12 from the side of the idle chamber 15, the striker will begin to move towards the chamber 16 of the stroke with lower air pressure, making idle.

The drummer 12, while continuing to move when interacting with the recess 2, blocks the radial outlet of the bypass channel 14 from the side of the idle chamber 15, and the air flow into the idle chamber 15 from the working stroke chamber 16 stops. In the idle chamber 15, the process of expanding the air contained therein begins, and in the working chamber 16, the process of compressing the remaining air and air in it begins to continue to flow through the intake throttle 6 in the partition 5 from the flow chamber 21.

Continuing the movement, the hammer 12 from the side of the idle chamber 15 will open the radial outlet channel 11 on the side surface of the tube 8 and through the longitudinal outlet channel 9, the channel 10 in the tube 8, and also the outlet channel 7 in the partition 5, the outlet annular chamber 22, the outlet channel 20 in the housing 18 of the handle 17 and the atmospheric chamber 23 formed by the housing 18 and the air ring 24, the air from the idle chamber 15 will be discharged into the atmosphere, and the air pressure in the idle chamber 15 is equalized to atmospheres st pressure.

Continuing the movement, the drummer 12, under the action of inertia forces, overcomes the air resistance from the side of the working stroke chamber 16, brakes and stops in the calculated position.

After stopping, the hammer 12 under the influence of air pressure from the side of the chamber 16 of the stroke will begin accelerated movement towards the chamber 15 of idle, making a stroke.

Simultaneously with the flow of air into the chamber 16 of the stroke through the intake throttle 6 in the partition 5 from the flow chamber 21, the air in the chamber 16 of the stroke will expand.

Continuing the movement, the hammer 12 will block the radial exhaust channel 11 in the tube 8, after which the idle chamber 15 will be disconnected from the atmosphere and the compression process of the air cut off in it will be carried out.

Upon subsequent movement, the firing pin 12 will open, when interacting with a recess 2 from the side of the idle chamber 15, the radial part of the bypass channel 14, made in the form of either a direct channel (see Fig. 1) or a cranked channel (see Fig. 2), made under angle to the generatrix of the surface of the striker 12, or a helical groove (see Fig. 3), after which air will begin to flow into the idle chamber 15 from the working stroke chamber 16.

As a result of such a message, the compression process of the cut off air and air coming from the working chamber 16 will continue in the idle chamber 15.

Overcoming the air backpressure from the side of the idle chamber 15, the striker 12 strikes the working tool 3.

The working process of the pneumatic hammer will be repeated and the next idle of the hammer 12 is carried out due to the pulse of the air pressure of the chamber 15 idle and the pulse of the rebound of the hammer 12 from the working tool 3.

Claims (1)

A pneumatic hammer containing a cylindrical body, a working tool held relative to the cylindrical body, a handle with an intake device and a body with an air supply and exhaust channels, a partition with an inlet throttle, an exhaust channel and an axial hole in which a tube with a longitudinal exhaust channel and a radial is mounted and fixed an outlet channel extending in its lateral surface, an annular outlet chamber with an outlet formed by a partition, a cylindrical body, and a body ohms of the handle, a flow chamber formed by the handle body and the partition and communicated by means of an air supply channel with a compressed air network, a drummer with a through axial channel for passing said tube, dividing the cavity of the cylindrical body into a working chamber from the partition side, constantly communicating with the flow chamber through the inlet throttle in the baffle, and the idle chamber from the side of the working tool, periodically communicated through radial and longitudinal exhaust channels in the tube and the outlet channel in the partition with access to the annular outlet chamber and through the outlet in the handle housing into the atmospheric chamber formed by the handle body and the air baffle ring, characterized in that a recess is made in the cylindrical body from the idle chamber side, and in the body of the hammer made bypass channel of circular cross section in the form of a direct channel, inclined to the axis of the drummer, or a cranked channel, and the bypass channel is made with a constantly open exit at the end of the drummer from ons of the working chamber and a radial exit in its lateral surface to the said recess of the idling chamber with the possibility of periodic communication of the working and idling chamber to each other in the closed radial outlet channel of the tube with the end face of the hammer from the side of the idling chamber.

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