RU2747152C1 - Pneumatic hammer - Google Patents

Abstract

FIELD: pneumatic tools.

SUBSTANCE: pneumatic hammer contains a cylindrical case, a working tool held relatively to the cylindrical case, a handle with a pre-chamber, an inlet device and a case with an outlet hole, a partition with an inlet throttle and an outlet channel, a tube with longitudinal and radial outlet channels on its side surface, and an annular outlet chamber formed by a partition, a cylindrical case and a handle case. A striker with a through axial channel for passing the said tube divides the cavity of the cylindrical case into a working stroke chamber on the side of the partition and an idle stroke chamber on the side of the working tool. In the wall of the annular part of the striker, a bypass channel is made with a separate output to its side surface and to the end of the striker from the side of the working stroke chamber. The bypass channel of the striker is provided with its coaxial continuation in the form of a drainage channel having a cross-sectional area less than the area of the bypass channel, and extending to the end of the striker from the side of the idle stroke chamber, with the formation by the said channels of a through-stepped bypass channel, which constantly communicates the said chambers of idle and working stroke with each other.

EFFECT: decreased air backpressure in the chambers of the working and idle stroke during the end of the working and idle stroke of the striker.

1 cl, 1 dwg

Description

The invention relates to the field of construction, in particular to pneumatic impact machines, and can be used for the destruction of strong materials in construction, mining and mechanical engineering.

Known device pneumatic hammer (A.S. USSR No. 1172692, 1986 B25D 9/04), containing a cylindrical body with a handle, an exhaust channel, a flow chamber, constantly communicating with an air-conducting channel with a network of compressed air, a striker separating the body cavity into the working chamber stroke, constantly communicating with the prechamber and alternately with the atmosphere, and the idle stroke, alternately communicating with the atmosphere and the throttle, moreover, in the body between the working stroke chamber and the prechamber there is a partition with a central hole with a coaxial tube installed and fixed in the hole, in which an additional air-conducting channel to the idle chamber, constantly communicating it with the flow chamber, and an exhaust channel, at one of the ends of which a throttle is installed, and the other is in communication with the atmosphere. The striker is installed coaxially to the tube with the ability to move along it.

The disadvantage of the described design is: in the working cycle of the working and idling chambers, air is injected into each of the chambers and the exhaust air is also discharged from each chamber, which leads to a significant unproductive air flow from the network when each of the chambers communicates with the atmosphere, which reduces the efficiency working cycle and hammer as a whole; an inlet channel into the idle chamber and an exhaust channel from the working and idle chambers are made in one tube for the air supply and exhaust air outlet, which leads to an increase in the transverse dimensions; The exhaust channel in the tube for the working and idle chambers causes an increase in the transverse dimensions of the channel to ensure the release of exhaust air during one cycle, which requires an additional increase in the transverse dimensions of the tube and the mass of the hammer as a whole.

The closest, in technical essence, the claimed (selected as a prototype) is a pneumatic hammer device (RF patent No. 2583571, 2016 B25D 9/04, B25D 9/08) containing: a cylindrical body; a working tool held relative to the cylindrical body; a handle with an inlet device; a partition with an outlet throttle valve and an axial hole in which a tube with a longitudinal outlet channel and a radial outlet channel extending to its lateral surface is installed and fixed; an annular outlet chamber with an outlet formed by a baffle, a cylindrical body, and a handle body; a flow chamber formed by the handle body and the baffle communicated by means of an air supply channel with a compressed air network; a striker with a through axial channel for passing the said tube dividing the cavity of the cylindrical body into a working stroke chamber from the side of the baffle, constantly communicating with the pre-chamber by means of an inlet throttle in the baffle; an idle chamber from the side of the working tool periodically communicating the cavity of the cylindrical body and the chamber of the working stroke, from the side of the partition constantly communicating with the prechamber by means of an inlet throttle in the partition; an idle chamber on the side of the working tool, periodically communicating with the atmosphere, of the radial longitudinal outlet channel in the tube; an outlet channel made in a partition with an outlet to an annular outlet chamber and through an outlet in the handle body to an atmospheric chamber formed by the handle body and an air baffle ring; a groove is made on the side of the idle stroke chamber, and the annular part of the striker contains a bypass channel with an outlet to the lateral surface of the striker with a permanently open outlet at the end of the striker from the side of the stroke chamber.

The disadvantage of the prototype is: significant air backpressure from the side of the working stroke chamber at the end of the idle stroke due to the compression of air by the moving striker, which is amplified with constant intake of network air from the prechamber by means of the throttle channel in the partition, as a result of which the striker starts braking prematurely and does not reach the calculated value course; significant air backpressure in the idling chamber at the end of the working stroke before the striker collides with the tool shank, due to the compression of the air cut off in the chamber and the air entering through the bypass channel made on the side surface of the striker when its radial channel exits into the annular groove of the idling chamber with by a sharp bypass of air from the chamber of the working stroke into its volume, as a result of which the hammer is decelerated with a loss of speed before collision, and, consequently, with a loss of shock impulse transmitted to the working tool.

The objective of the claimed invention is: reducing the air backpressure in the chambers of the working and idling during the period of the end of the working and idling of the striker by forming an air bypass channel between the chambers of the working and idling, constantly communicating the said chambers with each other with a drainage channel in the form of a stepped continuation with an exit to the end a striker with a smaller cross-sectional area facing the idle chamber.

The problem is solved by the fact that a pneumatic hammer containing a cylindrical body, a working tool held relative to the cylindrical body, a handle with an inlet device, a baffle with an inlet throttle, a tube with longitudinal and radial outlet channels, on its lateral surface, an annular outlet chamber with an outlet formed by a partition, a cylindrical body and a handle body with an air supply channel of compressed air from the network, a striker with a through axial channel for passing the said tube dividing the cavity of the cylindrical body into a working stroke chamber from the partition side, constantly communicating with the pre-chamber by means of an inlet throttle in the partition and a chamber idling from the side of the working tool, periodically communicated by means of the radial and longitudinal inlet channels of the tube, the outlet channel in the partition with an outlet to the annular outlet chamber and through the outlet in the handle housing in the outlet the bore chamber formed by the handle body and the air baffle ring, a groove is made in the cylindrical body on the side of the idle speed chamber, and the bypass channel in the wall of the annular part of the striker with a separate exit to its lateral surface and exit to the end face of the striker from the side of the working stroke chamber, according to the invention, a bypass the channel is provided with its coaxial continuation in the form of a drainage channel with a smaller cross-sectional area with an exit to the end face of the striker from the side of the idle chamber, forming a through stepped bypass channel connecting the above-mentioned chambers to each other.

The drawing (Fig. 1) shows a longitudinal section of a pneumatic hammer with a stepped bypass channel with an open outlet to both ends of the striker with a smaller cross-sectional area with an outlet to the butt of the striker from the side of the idle chamber.

The pneumatic hammer contains a cylindrical body 1 with a recess 2, a working tool 3 held by a spring 4 relative to the body 1, a partition 5 with an outlet choke 6 and an outlet channel 7, a tube 8 with a longitudinal outlet channel 9 and a lateral outlet channel 10, constantly communicating channels 7 and 9 among themselves. The radial outlet channel 11 on the lateral surface of the tube 8 is in constant communication with the longitudinal channel 9. The striker 12 divides the cavity of the cylindrical body 1 into an idle chamber 13 with a groove 2 on the side of the working tool 3 and a working stroke chamber 14 on the side of the partition 5. Bypass channel 15 in the wall of the annular part of the striker 12 is provided with its coaxial continuation in the form of a drainage channel 16 with an exit to the end of the striker 12 from the side of the idle chamber 13 with a smaller cross-sectional area and a radial channel 17 with an exit to the lateral surface of the striker 12 into the recess 2. The striker 12 is provided with an axial through channel 18 for passing the tube 8.

The area of the radial outlet 17 of the bypass channel 15 on the side surface of the striker 12 and the groove 2 of the idle chamber 13, in the position of the striker 12 contact with the working tool 3, is made not less than the cross-sectional area of the bypass channel 15.

The handle 19 contains an air inlet channel 20 and a housing 21 with the formation of a prechamber 22 of the network air from the side of the partition 5 and an annular chamber 23 formed between the housing 21, the cylindrical body 1 and the partition 5. The body 21 of the handle 19 is equipped with an outlet channel 24 with an outlet to the outlet chamber 25, formed between the housing 21 and an air deflector ring 26 which is detachably installed relative to it.

The body 21 by means of a threaded connection is sealed with respect to the cylindrical body 1 by the retainer 27 and is held by the annular casing 28.

After turning on the network air supply device (not shown in the drawing and can be any known from the design solution), the air enters through the air supply channel 20 in the handle 19 into the pre-chamber 22, from where through the inlet throttle 6 in the partition 5 into the chamber 14 of the working stroke in the cylindrical building 1.

With the air hammer in the position shown in FIG. 1, the air from the chamber 14 of the working stroke through the bypass channel, made in the annular part of the striker 12 in the form of a stepped through channel formed by the bypass channel 15, the drain channel 16 and the radial channel 17 with an outlet to the side surface of the striker 12 enters the idling chamber 13, formed by the recess 2 in the cylindrical body 1. When communicating between the idling chamber 13 and the working stroke chamber, the functions of the chambers change: the working stroke chamber 14 acquires the functions of a chamber with partial air displacement, the idling chamber 13 - the functions of the drainage chamber.

As a result of the above, in the chamber 14 of the working stroke, the air pressure rises slowly, and the air pressure in the chamber 13 of the idle stroke will be maintained higher due to its leakage from the chamber 14. Under the action of the air pressure on the end face of the striker 12 from the side of the chamber 13 of the idle stroke, the striker moves towards the chamber 14 of the working stroke, making an idle stroke.

The striker 12, continuing to move when interacting with the groove 2, overlaps the radial channel 17 with no less cross-sectional area of the channel 15, and the air will be bypassed only through the drainage channel 16 with a smaller cross-sectional area.

In the idling chamber 13, the process of air expansion continues, and in the working stroke chamber, the compression process continues, the air remaining in it and air continues to flow through the inlet throttle 6 of the partition 5 from the pre-chamber 22.

Continuing the movement, the striker 12 with its end on the side of the idling chamber 13 will open the radial outlet channel 11 on the lateral surface of the tube 8, and through the longitudinal inlet channel 9, channel 10 in the tube 8, as well as the outlet channel 7 in the partition 5, the outlet annular chamber 23, the outlet channel 24 in the housing 21 of the handle 19 and the outlet chamber 25 formed by the housing 21 and the air deflector ring 26, and the air from the idle chamber 13 will be vented to the atmosphere. The air pressure in the idle chamber 13 is equalized to atmospheric pressure due to the smaller cross-sectional area of the outlet of the drainage channel 16.

Continuing the movement, the striker 12, under the action of the inertial force, overcomes the air resistance from the side of the working stroke chamber 14, decelerates and stops in the calculated position.

After stopping, the striker 12 under the action of air pressure from the side of the chamber 14 of the working stroke begins to accelerate towards the chamber 13 of the idle stroke, making the working stroke.

Simultaneously with the flow of air into the chamber 14 of the working stroke through the inlet throttle 6 of the partition 5 from the pre-chamber 22, the air in the chamber 14 of the working stroke will expand due to an increase in its volume.

Continuing the movement, the striker 12 will block the radial outlet channel 11 in the tube 8, after which the idle chamber 13 will be disconnected from the atmosphere and the process of delayed compression of the air cut off in it, flowing from the chamber 14 of the working stroke through the drainage channel 16, will take place.

During the subsequent movement, the striker 12, when interacting with the groove 2 from the side of the idling chamber 13, will open the air inlet only before the striker collides with the working tool 3. After that, air begins to flow into the idling chamber 13 from the working stroke chamber 14, which will not significantly affect the growth counterpressure and premature braking of the striker 12, but will significantly increase the impulse of air pressure on the striker at idle and will provide the value of its design stroke and the corresponding values of the energy parameters of the working process.

Overcoming the air resistance from the side of the idle chamber 13, the striker 12 strikes the working tool 3.

The working process of the pneumatic hammer will be repeated and the next idle stroke of the striker 12 is carried out by adding to the impulse of air pressure from the side of the idle chamber 13 of the impulse of the rebound of the striker 12 from the working tool 3.

The use of the claimed invention makes it possible to carry out permanently partial bypass and drainage of air between the working and idle chambers with lower values of air backpressure in them, due to which at the end of the working stroke of the striker, partial displacement of air from the idle chamber in the pre-shock period is ensured, which makes it possible to increase the speed of the striker when collision with the working tool and increase the impact energy while reducing the air consumption from the network due to drainage and bypassing it from the working stroke chamber. When the striker is idling, the partial displacement of air from the working stroke chamber causes a decrease in the air backpressure on its side and excludes premature braking of the striker, which ensures the guaranteed value of its design stroke.

At the end of the working stroke, part of the air is bypassed from the idling chamber to the working stroke chamber, which increases the air pressure impulse from the side of the working stroke chamber and increases the impact speed without consuming air from the network. Thus, the proposed technical solution of a pneumatic hammer with a drainage process and a partial bypass of air between the chambers makes it possible to reduce the air consumption consumed from the network and to increase the impact energy transmitted to the working tool.

Claims (1)

Pneumatic hammer containing a cylindrical body, a working tool held relative to the cylindrical body, a handle with a body with an outlet, a pre-chamber and an inlet device, a baffle with an inlet throttle and an outlet channel, a tube with longitudinal and radial outlet channels on its lateral surface, an annular outlet chamber with an outlet formed by a partition, a cylindrical body and a handle body with an air supply channel of compressed air from the network, a striker with a through axial channel for passing the said tube dividing the cavity of the cylindrical body into the working stroke chamber from the side of the partition, constantly communicating with the pre-chamber by means of an inlet throttle in the partition, and the idle chamber on the side of the working tool, periodically communicated by means of the radial and longitudinal inlet channels of the tube, the outlet channel in the partition with an outlet in the annular outlet chamber and through the outlet hole tia in the handle body with the outlet chamber formed by the handle body and the air baffle ring, while in the cylindrical body on the side of the idle speed chamber a groove is made, and in the wall of the annular part of the striker there is a bypass channel with a separate exit to its side surface and to the end of the striker from the side of the working stroke chamber, characterized in that the bypass channel of the striker is provided with its coaxial continuation in the form of a drainage channel having a cross-sectional area less than the area of the bypass channel and extending to the end of the striker from the side of the idling chamber, with the formation of the mentioned channels of a through stepped bypass channel , which constantly communicates the mentioned idle and working chambers among themselves.

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