RU2634537C1 - Double-action compression-vacuum impact machine - Google Patents

Abstract

FIELD: machine engineering.

SUBSTANCE: machine has a body and a striker placed therein forming an upper chamber and a lower chamber connected with atmosphere, a vacuum-compressor installed in the upper part of the disc body forming chambers above and below the disc, a receiver is connected to the upper chamber, a magnetic lock for the striker is installed in the upper chamber, and a working tool. The chamber above the disc is permanently connected with atmosphere, and the vacuum-compressor is connected through a switch to a current source. The vacuum-compressor is a centrifugal compression-vacuum mechanism connected to a working medium distributor, which faces with a suction hole into the chamber under the disc, a cut from the upper chamber by a solid partition, and an exhaust hole into the chamber above the disc. The working medium distributor is arranged with for periodic connection of the chamber under disc with the upper chamber or the atmosphere, and the chambers above the disc with the upper chamber.

EFFECT: increased efficiency of machine operation and its reliability, simplified its structure.

3 cl, 1 dwg

Description

The technical solution relates to mining, namely to shock machines, and can be used for breaking monoliths, in construction for the destruction of obsolete foundations, during the reconstruction of buildings, when laying pipelines, and also in seismic exploration as a mechanical source of excitation of seismic waves at shallow depths .

Known compression-vacuum shock machine, the first option according to the patent of the Russian Federation No. 2455444, E21B 1/00, B25D 11/00, publ. 07/10/2012, Bull. No. 19, comprising a housing and a striker located 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.

The essential features of the analogue, which coincide with the essential features of the proposed technical solution, are: a housing and a striker placed in it, forming the lower and upper chambers, a vacuum compressor connected to the upper chamber, a magnetic retainer for the striker installed in the upper chamber, as well as the connection of the lower car cameras with atmosphere.

One of the disadvantages of this machine is its low impact energy, which depends only on the height of the body and the mass of the striker, which reduces its efficiency. In addition, the bulky and complex design of the machine reduces its reliability and mobility.

The closest in technical essence and the set of essential features is a double-action compression-vacuum impact machine according to the patent of the Russian Federation for utility model No. 156306, B25D 9/08, B25D 9/26, publ. 11/10/2015, Bull. No. 31, comprising a housing and a striker placed therein, forming the upper and lower chambers, a vacuum compressor connected to the upper chamber and at least one receiver connected to the upper chamber, a magnetic striker lock mounted in the upper chamber, and a working tool, while the lower chamber is connected to the atmosphere. The vacuum compressor is located in the upper part of the housing, it contains at least one pair of centrifugal compression-vacuum mechanisms installed opposite each other by suction openings having a common channel and connected to the disk forming the chambers above and below the disk, and the chamber above the disk is connected with the atmosphere and cutting off the aforementioned upper chamber and the chamber under the disk from the atmosphere, while said centrifugal compression-vacuum mechanisms are electrically connected to a three-position switch, which metrically connected to a current source.

The essential features of the prototype, which coincide with the essential features of the proposed technical solution, are: a body and a hammer placed therein, forming the lower and upper chambers, a vacuum compressor connected to the upper chamber, a magnetic clamp for the hammer, a working tool, as well as a connection of the lower chamber of the machine with the atmosphere. In addition, the centrifugal compression-vacuum mechanisms of the prototype are connected to the disk forming the chamber above and below the disk. The camera above the disk is connected to the atmosphere, and the camera below the disk is connected to the upper camera and is cut off from the atmosphere.

One of the disadvantages of this machine is its low shock frequency due to the need to switch centrifugal compression-vacuum mechanisms for direct and reverse stroke of the hammer, which significantly reduces the power of the machine, and therefore its efficiency. The need to use at least two centrifugal compression-vacuum mechanisms for carrying out work and placing them in the opposite direction inevitably leads to complication of the machine design (reduces the reliability of its operation), significantly increases the cost of the machine and its repair.

In addition, due to the rapid wear of the actuators (centrifugal compression-vacuum blades), since they work in the opposite direction, the life of the machine is reduced. The above significantly reduces the reliability of the machine.

The problem is to increase the efficiency of a double-action compression-vacuum impact machine by increasing the frequency and energy of impacts by applying a continuous operation scheme for one compression-vacuum mechanism and to increase the reliability of work by simplifying the design and increasing the life of its operation. In addition, the implementation of the scheme with one compression-vacuum mechanism can significantly reduce the cost of the machine and increase maintainability.

The solution to the problem is achieved in that in a double-action compression-vacuum impact machine comprising a body and a drum placed therein, forming an upper chamber and a lower chamber connected to the atmosphere, a vacuum compressor installed in the upper part of the body on a disk forming a chamber above and under the disk, a receiver connected to the upper chamber, a magnetic detent for the hammer mounted in the upper chamber, and a working tool, while the camera above the disk is constantly connected to the atmosphere, and the vacuum compressor is through a switch b - with a current source, according to the technical solution, the vacuum compressor is a centrifugal compression-vacuum mechanism connected to the distributor of the working medium, while the indicated centrifugal compression-vacuum mechanism faces the suction hole in the chamber under the disk, cut off from the upper chamber by a solid partition, and exhaust hole into the chamber above the disk, and the specified distributor of the working medium is made with the possibility of periodic connection of the camera under the disk with the upper chamber or atmosphere th, and the cameras above the drive with the top camera.

The specified set of features allows, without switching the centrifugal compression-vacuum mechanism, to operate the machine on the forward and reverse stroke of the striker and, thus, significantly increase the frequency and energy of impacts, and therefore its efficiency. The application of the scheme with the continuous operation of one centrifugal compression-vacuum mechanism significantly simplifies the design of a double-action compression-vacuum impact machine, which reduces its cost and increases the reliability and service life.

It is advisable that a double-action compression-vacuum machine be equipped with a pressure regulator of the working medium in the chamber above the disk mounted on its channel (for example, a crane). Changing the size of the exhaust hole in the chamber above the disk will smoothly increase or decrease the impact energy, which increases the efficiency of the machine.

It is advisable that the upper part of the machine body with a centrifugal compression-vacuum mechanism, a distributor of the working medium, a pressure regulator of the working medium and the receiver should be removable and adapted using nozzles for installation in housings of any diameter. This will significantly expand the scope of the machine and, as a result, increase its efficiency.

The essence of the technical solution is illustrated by an example of a specific embodiment of a double-acting compression-vacuum impact machine and a drawing, which shows a general view of the machine in a longitudinal section and in its initial position. Dashed lines show the pressure regulator of the working medium in the chamber above the disk.

The machine contains (see drawing) a housing 1, a drummer 2 placed therein, forming an upper chamber 3 and a lower chamber 4 connected to the atmosphere by channels 5, a vacuum compressor 6 mounted on a disk 7 forming a chamber 8 and 9 above and below the disk 7, respectively, the receiver 10, made, for example, in the form of an elastic shell and connected by the passage channels 11 of the mounting disk 12 to the upper chamber 3, a magnetic latch 13 for the hammer 2, mounted in the upper chamber 3, and a working tool 14. The camera above the disk 7 is connected with atmosphere channel 15. Vacuum compressor op 6 is electrically connected through switch 16 to a current source (not shown). The vacuum compressor 6 is a centrifugal compression-vacuum mechanism 17 facing the suction hole 18 into the chamber 9 under the disk 7, made with the possibility of periodic connection through the passageways 11 of the mounting disk 12 with the upper chamber 3 or the atmosphere using the distributor 19 of the working medium and cut off from the upper chamber 3 by a solid partition 20 and a mounting disk 12 with passage channels 11. The centrifugal compression-vacuum mechanism 17 with the exhaust hole 21 faces the chamber 8 above the disk 7. Distribute 19 the working medium consists of a working channel 22, containing a piston 24 spring-loaded with a spring 23, periodically connecting the chamber 8 above the disk 7 with the upper chamber 3 through the auxiliary channel 25 and the passage channels 11 of the mounting disk 12 and disconnecting it in the same way (in the lower position according to the drawing ) the chamber 8 above the disk 7 from the upper chamber 3, as well as the piston 26, spring-loaded with a spring 23 and rigidly connected by a rod 27 with the piston 24. A piston 26 disconnects the chamber 9 under the disk 7 from the upper chamber 3 through the auxiliary channel 25 and the passage channels 11 of the mounting disk 12. In the initial position, the chamber 9 under the disk 7 is connected to the atmosphere by a channel 28 with the possibility of overlapping this channel 28 in the lower (according to the drawing) position by a piston 26.

The machine can be equipped with a regulator 29 of the pressure of the working medium in the chamber 8 above the disk 7 mounted on its channel 15. The upper part 30 of the housing 1 with a vacuum compressor 6, a distributor 19 of the working medium, a regulator 29 of the pressure of the working medium in the chamber 8 above the disk 7 and receiver 10 can be made removable and adapted using nozzles (not shown) to install it in buildings 1 of any diameter.

The machine operates as follows. In the initial, lower (according to the drawing) position, the hammer 2 is located on the working tool 14. The centrifugal compression-vacuum mechanism 17 is disconnected by the switch 16 from the current source. When the switch 16 is turned on, the centrifugal compression-vacuum mechanism 17 starts to work, distilling the working medium from the atmosphere through the channel 28, the chamber 9 under the disk 7, the suction hole 18, the exhaust hole 21 and the channel 15 into the atmosphere, thereby blowing the centrifugal compression-vacuum mechanism 17. After purging, compress the spring 23, moving the pistons 24 and 26 to the lower (according to the drawing) position. The channel is shut off, which supplies the working medium to the upper chamber 3 through the auxiliary channel 25, through channels 11 of the mounting disk 12. Meanwhile, the camera 9 is connected under the disk 7 through the auxiliary channel 25 with the upper camera 3 through the through channels 11 of the mounting disk 12. As a result, the upper chamber 3 forms a rarefaction of the working environment. The drummer 2 moves up (according to the drawing) and engages in the upper position with the magnetic lock 13. The spring 23 is released, and it automatically moves the pistons 24 and 26 to the upper (according to the drawing) position, because they are rigidly connected by a thrust 27. An auxiliary channel 25 is opened connecting the chamber 8 above the disk 7 with the upper chamber 3 through the passage channels 11 of the mounting disk 12, the movement of the working medium through the working channel 22 and channel 28 from the atmosphere resumes.

Since the area of the channel 15 is significantly smaller than the area of the hammer 2, the compression force formed by the centrifugal compression-vacuum mechanism 17 tears the hammer 2 from the magnetic lock 13.

To increase the initial speed of the striker 2, a receiver 10 is used, the volume of the working medium in which increases the speed of the striker 2 throughout its entire travel.

The drummer 2 moves downward and at the end of the forward stroke strikes the working tool 14. The working medium from the lower chamber 4 is exhausted into the atmosphere through the channels 5. Upon subsequent compression of the spring 23, the cycle repeats.

To regulate the compression pressure in the upper chamber 3, and thus the impact energy, the machine can be equipped with a pressure regulator 29 of the working medium in the chamber 8 above the disk 7 mounted on its channel 15.

Acceleration of the striker 2 is not only due to gravity, but also additionally from the pneumatic effects of the vacuum compressor 6 and receiver 10, which allows this machine to be classified as a double-acting machine.

The removable upper part 30 of the housing 1 with a centrifugal compression-vacuum mechanism 17, a distributor 19 of the working medium, a regulator 29 of the pressure of the working medium in the chamber 8 above the disk 7 and the receiver 10 can be installed in cases of any diameter by means of appropriate nozzles, which greatly expands the capabilities of the machine.

Claims (3)

1. A double-action compression-vacuum percussion machine, comprising a body and a drum placed therein, forming an upper chamber and a lower chamber connected to the atmosphere, a vacuum compressor installed in the upper part of the body on a disk forming a chamber above and below the disk, a receiver, connected to the upper chamber, a magnetic clamp for the hammer, mounted in the upper chamber, and a working tool, while the chamber above the disk is constantly connected to the atmosphere, and the vacuum compressor through the switch is connected to a current source, characterized in that the vacuum compressor is made in the form of a centrifugal compression-vacuum mechanism connected to the distributor of the working medium and facing the suction hole into the chamber under the disk, cut off from the upper chamber by a solid partition, and the exhaust hole into the chamber above the disk, while the said medium distributor configured to periodically connect the camera under the disk to the upper chamber or atmosphere, and the camera above the disk to the upper chamber. 2. A double-action compression-vacuum impact machine according to claim 1, characterized in that it is equipped with a pressure regulator of the working medium in the chamber above the disk mounted on its channel. 3. The double-action compression-vacuum impact machine according to claim 2, characterized in that the upper part of the machine body with a centrifugal compression-vacuum mechanism, a medium distributor, a medium pressure regulator and a receiver is removable with the possibility of installation by means of nozzles in cases of any diameter .

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