SU1754433A1 - Impact-action compression-vacuum machine - Google Patents

Abstract

The invention relates to mechanical engineering, in particular to electric hammers. The aim of the invention is to increase reliability and reduce dimensions. The compression-vacuum machine comprises a housing, an actuator housed therein, a stepped cylinder with a piston located in its larger stage, kinematically connected with the actuator, and a hammer connected with an air cushion piston, as well as a working tool. The piston is made with a section located in a smaller cylinder step and forming a chamber at a larger stage that is permanently separated from a smaller chamber and communicating with a smaller step through the cylinder holes located under the lower plug of the piston section at its lower dead center. The design of the machine is made so that the striker on the final segment of its return stroke (toward the piston) after it closes the holes in the cylinder, which connect the chamber with a smaller cylinder step, is connected only to the piston section through a closed working chamber located in a smaller cylinder stages, excluding direct impact of impactors and pistons. 2 Il. VI JV

Description

The invention relates to mechanical engineering, in particular to electric hammers and perforators used in construction, geological exploration and drilling and blasting operations for the destruction of building materials and rocks and the formation of holes in them.

Percussion compression-vacuum machines are known, comprising a housing, an actuator housed therein, a stepped cylinder with a piston located in its larger stage, kinematically connected with an actuator and a striker, an airbag associated with the piston, and a working tool with which the drummer interacts .

In these machines, the larger and smaller cylinder stages communicate through holes in the wall separating both stages. In transient modes of a percussion machine, the magnitude of the movement of the projectile under the action of a vacuum may be greater than that regulated by the partition between the cylinder steps. There is a blow between the drummer and the partition, which reduces the reliability of the machine.

CO SO

Closest to the proposed technical entity is a compression-vacuum percussion machine, comprising a housing, an actuator housed in it with an axis, a stepped cylinder with a piston located in its larger gear, a kinematically connected with the actuator, and a smaller drummer.

In a known machine, there is no partition that separates the smaller and larger cylinder steps. However, with certain parameters of the percussion machine, the magnitude of the maximum displacement of the striker under the action of vacuum may be greater than the length of the smaller cylinder step, so that part of the hammer body may be in a larger cylinder step. At the same time, during the forward stroke of the piston, a cavity is formed between the cylindrical surface of the shock of the larger cylinder stage, in which the air cushion is compressed, and the hammer with its upper end can collide with the bottom of the piston. Straight collisions with a piston reduce the reliability of the machine.

The purpose of the invention is to increase the reliability of the compression-vacuum percussion machine and reduce its dimensions.

The goal is achieved by the fact that in a compression-vacuum percussion machine, comprising a housing, a drive cylinder with an axis, a stepped cylinder with a piston located in its larger step, kinematically connected with the drive, and a smaller drummer, the piston is made stepped, a smaller its stage is placed in a smaller cylinder stage with the formation of an air cushion between the ends of the piston and the impactor and is provided with channels connecting the large cylinder stage with its smaller stage at the maximum distance of the piston from si drive.

In the proposed machine, the hammer in the final segment of its return stroke (up towards the piston) after it closes the valve holes in the small cylinder stage is only connected with the small piston stage through a closed working chamber located at a lower cylinder level. my impact drummer and piston. At the same time, the rest of the path of the impactor is connected through the air cushion with the greater and lesser steps of the cylinder, and the nature of the operation of the machine is no different from the prototype. Preserving the working capacity of the prototype and at the same time eliminating possible impacts of the striker and the piston constitute the essence of the invention.

The piston is stepped, repeating a large cross-section and

small cylinder steps, makes it possible to change the direction of movement of the striker in its extreme upper position, not by direct impact of the striker and the piston, but through a closed working chamber,

0 formed by a drummer and a lower piston stage. Due to the absence of the impact of the hammer and piston, the reliability of the machine is improved. The presence of a closed working chamber, excluding the direct souc donations of the striker and the piston, makes it possible to reduce the length of the air cushion and, consequently, the overall dimensions of the machine.

FIG. 1 shows a compression-vacuum machine of percussion action in the initial position, when the striker is in the position of contact with the working tool, and the piston is in the position of maximum distance from the drive axis, the axis of rotation of the crank-connecting rod mechanism (bottom dead position, piston point), lengthwise cut; in fig. 2 - the same, in the position of the top dead center of the piston, when the hammer and the small piston stage form a closed working chamber.

0 The compression-vacuum percussion machine comprises a housing 1 (Fig. 1), a drive (not shown) located therein, on the axis of rotation of which a crank is placed a no-connecting rod converter.

5, the mechanism 3, and the stepped cylinder 4, which has a greater degree 5, respectively, with a larger diameter and a smaller degree 6, respectively, with a smaller diameter. A stepped piston 7 is located in the stepped cylinder 4, kinematically connected through a crank mechanism 3 to a drive. The piston 7 has a greater gear 8 and a smaller gear 9, mated respectively with the greater and lesser steps 5 and 6 of the cylinder 4. In the cylinder 4, at a lesser degree b, there is also a hammer 10 connected to the piston 7 A cushion 11. In the larger stage 5 of the cylinder 4 there is a chamber 12, bounded on its walls on one side and on the walls of the smaller stage 9 of the piston 7 and on the bottom 13 of its larger stage 8 on the other side (Fig. 2).

Chamber 12 communicates with a smaller stu5 cylinder block 4 b by channels 14 Holes 15 and 16, made in the cylinder walls, by which channel 14 communicates respectively greater and smaller steps 5 and 6 of cylinder 4. placed at the level of ends 13 and 17, respectively, greater and smaller steps 8 and 9 of the piston 7, which is located at a maximum distance from the axis 2 of rotation of the crank mechanism 3 or from the axis 2 of the drive (Fig. 1). The drummer 10 in its lowest position touches the working tool 18 fixed in the housing 1. In the extreme upper position (Fig. 2), the hammer 10, blocking the side surface of the orifice 16, forms between the end 17 of the lower stage 9 of the piston 7 and its own end 19 closed working chamber20.

When the striker 10 is located (Fig. 1) in its extreme lower position, the ends 13 and 17 of the piston 7 and its own end face 19 of the striker 10 form, along with the walls of the stepped cylinder 4, an air cushion 11.

The compression-vacuum percussion machine works as follows.

The piston 7 under the action of the actuator, moving from the position of the bottom dead center (Fig. 1) upwards, forms a vacuum in the air cushion 11, which forces the striker 10 to follow the piston 6 upwards. During its upward movement (reverse course), the impactor TO overlaps the openings 16 with its side surface, connecting channel 12 and smaller stage 6 of cylinder 4 with channel 14. In this case, a closed working chamber is formed between the impactor 10 and the end face 17 of the lower stage 9 of the piston 7. 20 (Fig. 2). The piston 7. reaches the top dead center, changes the direction of its movement and moves towards the striker 10. In the working chamber 20 between the striker 10 and the smaller step 9 of the piston 7, the pressure rises, decelerating the movement of the striker 10, and then changing its direction of movement. on the contrary. When the holes 16 are closed by the side surface of the striker 10, the movement of the piston 7 down towards the striker 10 is accompanied by compressed air and an increase in its pressure in chamber 12. During its forward stroke, the striker 10 opens the holes 16 with its side surface and communicates the chamber 12 and the smaller cylinder level 6 4. At the time of opening the openings 16, the overpressure generated in the chamber 12 during the direct stroke of the piston 7 is equalized with the pressure in the working chamber 19 and the further movement of the striker 10 to the impact occurs under the influence of pressure in the air A cushion 11, created by the piston 7 as in the known compression-vacuum machines of percussive action. During its forward course, the hammer 10 interacts with the working tool 18. Then the cycle repeats.

Thus, the execution of the 7-step piston, having the construction coupled to the 5-step cylinder 4, and the presence of the channels 14. which communicate both stages of the cylinder 4, allow the piston 7 to interact with the hammer 10 when the latter reaches its extreme 10 upper position through the closed working chamber 20 and exclude the direct impact of the hammer 10 and the piston 7, which increases the reliability of the machine. The connection by channels 14 of both stages 5 and 6 of the cylinder 15 to 4 in the position of maximum removal of the piston 7 from the axis 2 of the drive or axis 2 of rotation of the crank mechanism 3 is optimal.

As for the placement of the holes 15.

0 then it is fairly obvious, and the placement of the holes 16 closer to the axis 2 from the optimum value described above may result in the impact of the striker 10 with the bottom 17 of the small piston 9 of the piston 7. With this distance of the holes 16, they are in the full stroke zone of the small stage 9 of the piston 7. When the working chamber 20 is communicated through the openings 16 with the chamber 12 that is much larger in volume during the forward stroke of the piston 7

0, the moment when the striker 10 is in the zone of the working chamber 20, the air in the latter is distributed through the channels 14 and the chamber 12 and gives the piston 7 an opportunity (direct collision with the striker 10 that t

5 reduces the reliability of the machine. ,, x,

In cases where 4 holes 16 are located in a cylinder farther from axis 2 than their optimum position, as described above, working chamber 20 becomes the rig height

0 is greater than the full stroke of the piston 7. In this case, the nature of the movement of the striker 10 in the zone of the working chamber 20 depends on the radius of the crank of the crank-connecting rod mechanism 3, and the character of the movement of the striker

5 10 in the area of the air cushion 11 until the holes 16 are blocked by the side surface of the striker 10 depends on the magnitude of the reduced crank radius of the crank-connecting rod mechanism 3, which

0 more simple radius is proportional to the ratio of areas of a greater degree 8 to a smaller degree 9 of the piston 7, But the greater the radius of the crank, the higher the impact energy of the striker 10. Therefore, the

5 most of its path drummer 10 passes under the action of a larger radius of the crank (in this case, the reduced radius of the crank), the higher the impact energy of the striker 10 and, consequently, the energy parameters of the machine as a whole.

From this point of view, the placement of the holes 16 should be such that the height of the working chamber 20 is as low as possible, but, taking into account the need to eliminate the impact of the end 17 of the small stage 9 of the piston 7 with the hammer 10, the height of the working chamber 20 should not be less than the full stroke of the piston 7 All this makes it necessary to place the holes 16 at the level of the end face 17 of a smaller step 9 of the piston 7, which is at the maximum distance from the axis 2 of rotation of the crank mechanism 3 or the axis 2 of the drive.

The presence in the device of a stepped piston 7 coupled with a stepped cylinder 4 allows simultaneously reducing the overall dimensions of the machine. If in the prototype, in order to eliminate piston and impactor collisions, the length of the airbag is set longer than the maximum stroke of the impactor in the steady state operation, then in the proposed device the length of the airbag 11 can be significantly less than the maximum stroke of the impactor 10, since the direct impactor of the impactor 10 and piston 7 is impossible due to the presence between the last closed working chamber 20. Reducing the length of the air cushion 11 leads to the same reduction in the overall size of the machine.

The economic effect of using the proposed device is to increase reliability.

All other things being equal, the device allows a 2-3 times increase in the life of the machine.

For example, in a compression-vacuum percussion machine, made in

According to the prototype, a total of about 100 hours was achieved. At the same time, to exclude a direct impact of the piston and the impactor, the latter is equipped with a rubber damper, the operation time of which is about 100 hours. After the destruction of the shock absorber and the occurrence of direct impacts of the impactor and piston, the machine it remains for a few minutes and then the breakdowns of the parts of the crank drive gearbox, gearbox, and the engine occur.

The implementation of the compression-vacuum machine in accordance with the invention eliminates the possibility of the appearance of collisions of the piston and the impactor. At the same time, the resource of the entire machine is limited by the weakest node, the engine. Its resource, depending on the working conditions, is

200-300 hours. At the same time, this is the resource of the entire impact machine.

Claims (1)

Invention Formula A compression-vacuum percussion machine, comprising a housing, an actuator with an axis, a stepped cylinder with a piston located in its larger stage, kinematically connected to the Drive and, to a smaller extent, a drummer, characterized in that, in order to increase reliability and reduce overall dimensions, the piston is made stepwise, its lower level is placed in a smaller cylinder steps with the formation of an air cushion between the ends of the piston and the striker, and is provided with channels connecting the large cylinder level with its smaller step at the maximum distance of the piston from the drive axis. Fig 2.