RU2701006C1 - Double action compression-vacuum impact machine - Google Patents

Abstract

FIELD: construction; mining.

SUBSTANCE: invention relates to mining and construction – to impact machines, is used in breaking monoliths, for destruction of obsolete foundations during reconstruction of buildings and pile driving, as well as in seismic survey as source of excitation of seismic waves at shallow depths. Machine comprises housing and hammer arranged therein, forming lower and upper chambers, vacuum compressor, hammer retainer made in the form of a magnet and installed in the housing, a rotary distributor of the working medium with a gate, constantly connected to the atmosphere and alternatively with a compression channel with a vacuum compressor. Working fluid depressurisation check valve is connected to the lower part of the housing. Said rotary distributor of working medium located in upper chamber is connected alternately by vacuum channel with vacuum compressor, and its gate, rigidly connected with bottom of rotary distributor of working medium in its lower part and equipped with rotary switch with torsion spring, is installed with possibility of alternate connection of upper chamber with compression and vacuum channels of vacuum compressor. Lower chamber is constantly connected to atmosphere. Above check valve is installed above the hammer in its lower position, and the hammer retainer is mounted on the mounting disc and spring-loaded relative to it.

EFFECT: higher efficiency and reliability of machine operation.

1 cl, 2 dwg

Description

The technical solution relates to mining and construction, namely to shock machines, and can be used for breaking monoliths, for destroying obsolete foundations during reconstruction of buildings and driving piles, as well as in seismic exploration as a source of excitation of seismic waves at shallow depths.

Known compression-vacuum shock machine according to the patent of the Russian Federation No. 2455444, ЕВВ 1/00, В25D 11/00, publ. 07/10/2012, Bull. No. 19, the first option, comprising a housing and a striker placed therein, forming the lower and upper chambers, a vacuum compressor connected to the upper chamber, a striker for the striker installed in the upper part of the housing, and a working tool. The machine is equipped with a control unit connected to a vacuum compressor, and the clamp for the hammer is made in the form of a magnet with a control coil connected to the control unit, while the lower chamber is connected to the atmosphere.

Common features of the analogue and the proposed technical solution are: a housing and a drummer located in it, forming an upper chamber and a lower chamber connected to the atmosphere, a vacuum compressor connected to the upper chamber, a striker for a hammer in the form of a magnet installed in the housing, a working tool.

The disadvantage of this machine is its low impact energy, as such a machine can only work under the influence of gravitational forces and only in an upright position, which dramatically reduces its efficiency. In addition, the introduction of a control unit into the machine complicates and increases the cost of its design, leads to more frequent breakdowns, which reduces the reliability of its operation.

The closest in technical essence and the set of essential features is a compression-vacuum impact machine according to the patent of the Russian Federation for utility model No. 147963, E02D 7/10, B25D 9/16, publ. 11/20/2014, Bull. No. 32, the second option, comprising a housing and a drummer located in it, forming the lower and upper chambers, a vacuum compressor, a retainer for the hammer, made in the form of a magnet with a control coil and installed in the upper part of the housing. The machine is equipped with a rotary two-line distributor of the spool type working medium permanently connected to a vacuum compressor, alternately with two channels - with the lower and upper chambers and the atmosphere and equipped with a switching sensor installed with the possibility of interaction with the valve of the said distributor and the control magnet coil.

Common features of the prototype and the proposed technical solution are: a housing and a hammer placed therein, forming the lower and upper chambers, a vacuum compressor, a striker for the hammer, made in the form of a magnet and installed in the housing, a rotary distributor of the working medium with a damper constantly connected to the vacuum -compressor.

The disadvantage of this machine is its low efficiency due to the need to use only the compression functions of a vacuum compressor. Using a magnet with a control coil, as well as a switching sensor, i.e. electronic equipment, complicates, increases the cost, increases the possibility of machine breakdown due to dynamic processes during its operation, which leads to a decrease in the reliability of the machine. The location of the rotary distributor outside the machine body increases its overall dimensions and limits the possibility of use in hard-to-reach places (for example, cellars, small rooms, narrow drifts in mines), which also reduces its efficiency. The need to seal the lower chamber increases the complexity of the design of the machine in the manufacture and assembly and, accordingly, its cost. Switching connections (hoses, pipes, etc.) supplying the working medium from the rotary distributor of the working medium to the upper and lower chambers increase the leakage of the working medium, while the pressure of the working medium at the entrance to the upper and lower chambers is reduced, which reduces energy and frequency of strokes, and therefore the efficiency of the machine.

The problems are to increase the efficiency and reliability of the double-acting compression-vacuum impact machine due to the use of both the compression and vacuum channels of the vacuum compressor, and the location of the rotary distributor of the working medium with a shutter inside the machine body, as well as the refusal to use electronic equipment in it designs.

The solution to the problems is achieved by the fact that in a double-action compression-vacuum percussion machine containing a body and a striker placed in it, forming the lower and upper chambers, a vacuum compressor, a striker for a striker made in the form of a magnet and installed in the body, a rotary distributor of the working medium with a damper, constantly connected to the atmosphere and alternately a compression channel with a vacuum compressor, and a check valve of the working medium pressure relief valve is connected to the lower part of the housing, according to the technical solution the aforementioned rotary distributor of the working medium located in the upper chamber is alternately connected by a vacuum channel to the vacuum compressor, and its shutter, rigidly connected to the bottom of the rotary distributor of the working medium in its lower part and equipped with a rotary switch with a torsion spring, is mounted with the possibility of alternately connecting the upper chambers with compression and vacuum channels of the vacuum compressor, while the lower chamber is constantly connected to the atmosphere, said non-return valve is installed above the ud nick in its lowest position and lock for the striker is mounted on the mounting disc and is spring-loaded relative to it.

The use of the compression and vacuum channels of the vacuum compressor to ensure the duty cycle of the machine significantly increases its efficiency, since it involves refusing to seal the lower chamber and partially sealing the upper chamber, in which the rotary distributor of the working medium (semiautomatic device) is located, which mechanically controls the duty cycle, which simplifies the design of the machine and reduces the cost of its manufacture and assembly.

The location of the rotary distributor of the working medium in the machine body increases work efficiency by reducing its overall dimensions and allows its operation in hard-to-reach places (basements, mines, etc.). A significant reduction in the length of switching connections (hoses, pipes, etc.) reduces the leakage of the working medium, the probability of their damage, the relative alternating pressure of the working medium in the upper chamber increases, while the energy and frequency of impacts of the machine increase, which leads to an increase in efficiency and reliability her work.

The rejection of sophisticated electronic equipment that quickly breaks down due to dynamic loads also increases the reliability of the machine.

The spring-loaded clamp for the hammer mounted on the mounting disk allows you to absorb the energy of the reverse stroke of the hammer, preventing the machine from being thrown up when the hammer and spring-loaded clamp interact, as well as its breakdown.

It is advisable to install a retainer for the striker in the middle part of the body, which, when the stroke of the striker is reduced, will significantly increase the volume of the upper chamber, which in this case acts as a receiver, which makes it possible to increase the impact energy by a factor of 1.5–2.

The essence of the technical solution is illustrated by an example of a specific embodiment of a double-action compression-vacuum impact machine (hereinafter referred to as the machine) and the drawings of Fig. 1,2, where Fig. 1 shows a general view of the machine in longitudinal section in the initial position, Fig. 2 - section A -A in figure 1, the arrows in figure 1,2 show the movement of the working environment.

The machine contains (1, 2) a housing 1, a drummer 2 located therein, forming a lower chamber 3 and an upper chamber 4, a vacuum compressor 5, a retainer 6 for a hammer 2, made in the form of a magnet and installed in the middle part of the housing 1, a rotary distributor 7 of the working medium (hereinafter referred to as the distributor 7), consisting of a bottom 8 and rigidly attached to it at the bottom of the shutter 9. The inner side surface of the distributor 7 is the upper part of the housing 1, the upper surface is its cover (Fig. not indicated). The elements of the distributor 7: the bottom 8, the shutter 9, the upper part of the housing 1 and its cover form the working chamber of the distributor 7 (pos. Not indicated). The damper 9 is spring-loaded with a torsion spring 10 against the stop 11 on the housing 1 when the working medium pressure is pumped into the upper chamber 4 by a vacuum compressor 5 through the compression channel 12. The stop 13 on the housing 1 is designed to fix the distributor 7 in the position when the upper chamber 4 is connected by a vacuum channel 14 with a vacuum compressor 5. The distributor 7 is constantly connected to the atmosphere through an opening 15 in the upper part of the housing 1, and the lower chamber 3 through the openings 16 of the housing 1. The damper 9 of the distributor 7 is rigidly connected using a rod (pos. started) to the rotary switch 17 with a torsion spring 10. To purge the machine at idle of the hammer 2, as well as to relieve the pressure of the working medium in the upper chamber 4 at the time of impact by the hammer 2 above the latter, a check valve 18 for relieving the pressure of the working medium is connected to the housing 1. The latch 6, made in the form of a magnet, is installed in the housing 1 on the mounting disk 19 having holes. To adjust the energy of the impact, the mounting disk 19 can be moved and fixed at different levels of the housing 1. To absorb the return stroke of the hammer 2 between the latch 6 and the mounting disk 19, a spring 21 is installed on the pin 20 mounted for movement in the central hole of the mounting disk 19.

The machine operates as follows. In the initial (lower) position of the hammer 2, the operator turns on the vacuum compressor 5. Through the compression channel 12 of the vacuum compressor 5, the working medium enters the upper chamber 4 and is discharged into the atmosphere through the check valve 18 for dumping the working medium. Through the hole 15 of the distributor 7, located in the upper part of the housing 1, the working chamber formed between the cover and the wall of the housing 1, the bottom 8 and the valve 9 of the distributor 7, the vacuum channel 14 of the vacuum compressor 5, the working medium from the atmosphere enters the vacuum compressor 5. To cock the hammer 2, the operator turns the rotary switch 17. The damper 9, rigidly connected to the bottom 8 of the distributor 7, rotates to the stop 13 of the housing 1. The working medium through the compression channel 12, the working chamber of the distributor 7, the hole 15 of the distributor 7 it is exhausted into the atmosphere, and the vacuum channel 14 is connected to the upper chamber 4, in which a vacuum is created, as a result of which the striker 2 moves up to contact with the latch 6. The spring 21, compressing, absorbs the energy of the return stroke of the striker 2, preventing the machine from bouncing from the working tool and its breakdown. After fixing the striker 2 on the latch 6, the operator releases the rotary switch 17, which returns the damper 9 and the bottom 8 of the distributor 7 to the initial position to the stop 11 of the housing 1 by means of a torsion spring 10. The working medium is pumped into the upper chamber 4, which also serves as a receiver. through the compression channel 12 from the vacuum compressor 5. When the maximum pressure of the working medium in the upper chamber 4 is reached, which exceeds the attractive force of the hammer 2, it detaches from the retainer 6. The hammer 2 moves down, where in The end of the forward stroke strikes the working tool (pos. not indicated). At the same time, from the atmosphere through the hole 15 and the specified working chamber, the vacuum channel 14, the working medium enters the vacuum compressor 5. During seismic exploration of the machine, the operator, having analyzed the quality of the receiving signal, can change the impact energy by moving the mounting disk 19 of the housing 1 up or down. For breaking monoliths, the operator can correct the working tool (for example, a wedge) and continue to work further. The working cycle is repeated with the necessary rational frequency of striking by the hammer 2 on the working tool.

Acceleration of the striker 2 occurs not only due to gravity, but also additionally from the pneumatic action of the vacuum compressor 5 and from the installation of the retainer 6 for the striker 2 in the middle of the housing 1, while the upper chamber 4 acts as a receiver, which allows this machine to be classified as double action machines.

Claims (2)

1. A double-action compression-vacuum percussion machine, comprising a housing and a striker placed therein, forming the lower and upper chambers, a vacuum compressor, a striker for the striker, made in the form of a magnet and installed in the housing, a rotary distributor of the working medium with a shutter, constantly connected with the atmosphere and alternately a compression channel with a vacuum compressor, and a check valve for the pressure relief of the working medium is attached to the lower part of the housing, characterized in that the said rotary distributor is working The redhead located in the upper chamber is alternately connected by a vacuum channel with a vacuum compressor, and its shutter, rigidly connected to the bottom of the rotary distributor of the working medium in its lower part and equipped with a rotary switch with a torsion spring, is installed with the possibility of alternately connecting the upper chamber to the compression vacuum channels of the vacuum compressor, while the lower chamber is constantly connected to the atmosphere, the said check valve is installed above the hammer in its lower position, and the retainer for rnika mounted on the mounting disc and is spring-loaded relative to it. 2. A double-acting compression-vacuum impact machine according to claim 1, characterized in that the latch for the hammer is installed in the middle of the body.

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