RU2630931C1 - Adjustable compression-vacuum shock machine of double action - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: machine comprises a housing and a striker arranged therein, forming the upper chamber and the lower chamber, a vacuum compressor located at the upper part of the housing, connected to the upper chamber and comprising at least one pair of centrifugal compression-vacuum mechanisms mounted oppositely to each other with suction openings connected to the disc and having a common channel through an opening in this disc, which forms chambers above and below the disc in the upper housing part. The chamber above the disc is connected to the atmosphere, and cuts off said upper chamber and the chamber under the disc from the atmosphere. Said centrifugal compression-vacuum mechanisms are electrically connected to a three-position switch electrically connected to the current source, a receiver connected to the upper chamber, a magnetic lock for the striker, installed in the upper chamber, and a working tool. The lower chamber is connected to the atmosphere. The receiver is located in the housing between the upper chamber and the vacuum compressor and is connected to the upper chamber through the openings of the centering disk separating the receiver from the upper chamber, and to the vacuum compressor - through the openings in the mounting disc separating the vacuum compressor from the receiver. The magnetic lock for the striker is connected to a regulator located in the receiver and made with the possibility to change its length.

EFFECT: ensuring the possibility to expand the energy of impacts and the frequency, to avoid pressure losses during the flow-over from the receiver to the upper chamber, to reduce the machine dimensions by width, and to work in hard-to-reach places.

3 cl, 1 dwg

Description

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

Known compression-vacuum shock machine (hereinafter referred to as the machine) according to the patent of the Russian Federation No. 2455444, ЕВВ 1/00, B25D 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.

One of the disadvantages of this impact machine is the low impact energy, which depends on the height of the body and the mass of the hammer, 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. in bull. No. 31 November 10, 2015, containing a housing and a drummer located 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 latch for the hammer, installed in the upper chamber, and a working tool, while the lower chamber is connected to the atmosphere. The vacuum compressor located in the upper part of the housing 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 to 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 electrically connected to a current source.

The disadvantage of this machine is the constant in magnitude of the impact energy due to the unchanged length of the stroke of the striker. In addition, after hitting a working tool in the upper chamber of the machine (even if you immediately turn off the energy supply to the compression-vacuum mechanism), the pressure inertially increases, which has a harmful reactive effect on the hammer, and through it on the working tool, while the body comes off from the working tool, causing difficulties in the work of the operator.

The location of the receiver outside the machine body and its execution in the form of an elastic shell is a constructive disadvantage during operation and transportation of the machine, as the use of an elastic receiver in narrow basements, in the forest, etc. It leads to mechanical damage, which destroys the machine. In addition, as a result of the transfer of the working medium from the receiver to the upper chamber through the hole in the housing, the pressure that affects the projectile decreases, which leads to a decrease in the energy parameters (energy of impacts and frequency) of the machine, and in general its operation efficiency.

The technical objectives of the proposed solution are to increase the operational efficiency of a double-acting adjustable compression-vacuum percussion machine due to the possibility of expanding its energy parameters (impact energy and frequency) by continuously controlling the stroke length of the projectile, as well as by eliminating the pressure loss of the working medium during overflow from the receiver into the upper chamber, and increasing the reliability by eliminating the possibility of mechanical damage to the receiver and eliminating inertial reactive systems l in the upper chamber arising after hitting a working tool.

The solution to these problems is achieved by the fact that in an adjustable double-acting compression-vacuum impact machine (hereinafter referred to as the machine), comprising a housing and a drummer located therein, forming the upper and lower chambers, a vacuum compressor located in the upper part of the housing connected to the upper chamber and containing at least one pair of centrifugal compression-vacuum mechanisms installed opposite each other by suction openings connected to the disk and having a common channel through an opening in this disk, which calls the chambers above and below the disk in the upper part of the housing, the camera above the disk connected to the atmosphere, and cuts off the aforementioned upper chamber and the camera under the disk from the atmosphere, while the centrifugal compression-vacuum mechanisms are electrically connected to a three-position switch, which is electrically connected to the source current, a receiver connected to the upper chamber, a magnetic clamp for the hammer mounted in the upper chamber, and a working tool, while the lower chamber is connected to the atmosphere, according to the technical To this solution, the receiver is located in the housing between the upper chamber and the vacuum compressor and is connected to the upper chamber through the holes of the centering disk separating the receiver from the upper chamber, and with the vacuum compressor through the holes in the mounting disk separating the vacuum compressor from the receiver, the magnetic lock for the hammer is connected to a regulator located in the receiver and configured to change its length.

The ability to move the magnetic lock for the striker over the height of the body using the controller located in the receiver allows you to smoothly change the stroke length of the striker in solving various tasks of seismic exploration, construction and mining, thereby expanding the range of energy parameters of the machine (impact energy and frequency), which significantly increases the efficiency of the machine.

The location of the receiver inside the machine, i.e. made of non-elastic material, as in the prototype, avoids damage to it in hard-to-reach places (narrow basement, forest, narrow mine passages, etc.), reduces the width of the machine and, as a result, increases reliability, and also eliminates loss of pressure of the working medium in the upper chamber due to the lack of flow from the receiver into the said chamber, which increases the power of the machine, and therefore, its efficiency.

It is advisable that a check valve be installed in the opening of the housing made above the hammer in its lower position. This makes it possible to significantly reduce the pressure of the working medium in the upper chamber and thereby eliminate the inertial reactive forces in it that arise after hitting the working tool, which significantly increases the reliability of the machine.

It is advisable that the upper part of the housing with a vacuum compressor was removable and adapted using nozzles for installation in housings of any diameter. This makes it possible to increase the efficiency of the machine by expanding the possibility of its application.

The essence of the technical solution is illustrated by an example of a specific design of the machine and a drawing, which shows a General view of the machine in longitudinal section in the initial position.

The machine contains (see drawing) a housing 1, a drummer 2 located therein, forming the upper 3 and lower 4 chambers, a vacuum compressor (pos. Not indicated) connected to the upper chamber 3 and containing at least one pair of centrifugal compression-vacuum mechanisms, namely the lower 5 and upper 6, mounted opposite each other by suction holes 7 and 8, respectively, connected to the disk 9 and having a common channel 10 through the hole (pos. not indicated) in the disk 9. The disk 9 forms chambers (pos. not marked) above and below the disk 9. The receiver 11 is located in pus 1 between the upper chamber 3 and the vacuum compressor and is connected to the upper chamber 3 through the holes 12 of the centering disk 13 separating the receiver 11 from the upper chamber 3, and with the vacuum compressor through the holes 14 in the mounting disk 15 separating the vacuum compressor from receiver 11. Disc 9 cuts off the upper chamber 3, the receiver 11 and the camera under the disc 9 from the atmosphere. A magnetic latch 16 for the hammer 2 with dielectric plates 17 is installed in the upper chamber 3 and is connected elastically to the mounting disk 15, for example, by means of a spring (pos. Not indicated). The lower 5 and upper 6 centrifugal compression-vacuum mechanisms are connected by electrical connections 18 to a three-position switch 19, which is electrically connected to a current source 20. A cover 21 is provided from rain, snow and dust. The lower chamber 4 is constantly connected to the atmosphere through the windows 22 of the housing 1. The chamber above the disk 9 is connected to the atmosphere through the windows 23 of the housing 1. The hammer 2 in its initial position is located on the working tool 24, which is made in in the form of a plate (in the drawing) for seismic exploration, or in the form of an anvil - for driving pipes, or in the form of a chisel - in mining for breaking monoliths. Work tool 24 can be attached to the lower part of the housing 1 or not. The upper part 25 of the housing 1, in which the vacuum compressor is located, can be made removable and adapted using nozzles (not shown) to install it in the housing 1 of any diameter. The regulator 26, located in the receiver 11 and configured to change its length, consists of a lower 27 and upper 28 rods and an adjusting sleeve 29. The centering disk 13 is attached to the lower rod 27 by a sleeve 30. In the housing 1, above the hammer 2 in its lower position (see drawing), a hole can be made (pos. not indicated) in which the check valve 31 is installed.

The machine operates as follows. In the initial (lower) position, the hammer 2 is located on the working tool 24, the three-position switch 19 is in the neutral (middle) position, the centrifugal compression-vacuum mechanisms - lower 5 and upper 6 - are disconnected from the current source 20. Depending on the required impact energy, by means of the regulator 26, by means of the rods 27, 28 and the adjusting sleeve 29, the magnetic lock 16 is moved along the height of the housing 1, while the stroke length of the hammer 2 is set. The check valve 31 is closed. When the three-position switch 19 is moved to the upper position, the upper 6 centrifugal compression-vacuum mechanism is turned on by electrical connection 18 from the current source 20, which, through the suction hole 8, pumps out the working medium from the upper chamber 3 through the holes 12 in the centering disk 13, the holes 14 of the mounting disk 15 and the common channel 10 of centrifugal compression-vacuum mechanisms - lower 5 and upper 6 - into the chamber above the disk 9, then through the windows 23 of the housing 1 it exhausts it into the atmosphere. In the chamber under the disk 9, in the upper chamber 3 and in the receiver 11, a vacuum is formed, and the lower chamber 4 is connected by the windows 22 of the housing 1 with the atmosphere. Drummer 2 starts to move up. In the upper position, the firing pin 2 is coupled through dielectric plates 17 with a magnetic lock 16. The three-position switch 19 is turned into a neutral position, disconnecting the upper 6 centrifugal compression-vacuum mechanism from the current source 20. When translating the three-position switch 19 to the lower position, by means of electrical connection 18 from the current source 20, the lower 5 centrifugal compression-vacuum mechanism is turned on. In the chamber under the disk 9, the pressure of the working medium is created, injected by the lower 5 centrifugal compression-vacuum mechanism from the atmosphere through the windows 23 of the housing 1, then the common channel 10 of the centrifugal compression-vacuum mechanisms of the lower 5 and upper 6, through the suction holes 8 and 7, windows 14 the mounting disk 15 and the window 12 of the centering disk 13. The upper chamber 3 and the receiver 11 are filled with a working medium with an increase in its pressure in them until it exceeds the attractive force of the striker 2 with a magnetic lock 16. The striker 2 breaks away from the mag thread lock 16 and begins the direct stroke of the striker 2. At the end of the direct stroke, the striker 2 strikes the working tool 24. The check valve 31 opens, relieving excess pressure of the working medium in the chamber under the disk 9 to atmospheric. When translating the three-position switch 19 in the upper position, the cycle repeats.

Thus, the acceleration of the striker 2 occurs not only due to gravity, but also additionally from the pneumatic effects of the vacuum compressor and receiver 11, which allows this machine to be classified as a double-acting machine.

The removable upper part 25 of the housing 1 with a vacuum compressor can be installed in the casings of any diameter by means of appropriate nozzles, which greatly expands the possibilities of using the machine.

Claims (3)

1. An adjustable double-acting compression-vacuum percussion machine, comprising a housing and a striker placed therein, forming the upper and lower chambers, a vacuum compressor located in the upper part of the housing, connected to the upper chamber and containing at least one pair of centrifugal compression-vacuum mechanisms installed opposite each other by suction openings connected to the disk and having a common channel through the hole in this disk, which forms chambers above and below the disk in the upper part of the housing, and The space above the disk is connected to the atmosphere and cuts off the aforementioned upper chamber and the chamber under the disk from the atmosphere, while the centrifugal compression-vacuum mechanisms are electrically connected to a three-position switch, which is electrically connected to a current source, a receiver connected to the upper chamber, a magnetic lock for a drummer mounted in the upper chamber and a working tool, while the lower chamber is connected to the atmosphere, characterized in that the receiver is placed in the housing between the upper chamber and the vacuum com a pressor and is connected to the upper chamber through the holes of the centering disk separating the receiver from the upper chamber, and to the vacuum compressor through the holes in the mounting disk separating the vacuum compressor from the receiver, while the magnetic clamp for the hammer is connected to the controller located in the receiver and made with the possibility of changing its length. 2. An adjustable double-acting compression-vacuum impact machine according to claim 1, characterized in that a non-return valve is installed in the housing opening made above the drummer in its lower position. 3. An adjustable double-acting compression-vacuum impact machine according to claim 1 or 2, characterized in that the upper part of the housing with a vacuum compressor is removable and adapted using nozzles for installation in casings of any diameter.

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