KR101685690B1 - Driving pile machine - Google Patents

Abstract

The present invention relates to a mechanical and pneumatic pile driver. The mechanical and pneumatic pile driver comprises a main expandable room (20, 20), a main expandable piston (30, 30), a rod pipe (32), and a weight piston (40) in order to generate high-output pneumatic driving force in a lightweight and small structure using the short stroke of the piston and the reduced eccentricity of a crank shaft.

Description

{Driving pile machine}

The present invention relates to a mechanical pneumatic hermetic device, and more particularly, to a mechanical pneumatic hermetic device in which a high output pneumatic hitting force is generated in a small-sized lightweight structure by a short stroke of a piston and a reduced eccentricity of a crankshaft.

In general, a hanger is a hammer type device that applies a continuous load to crush a file or the like, and the hammer connected to the connecting rod is linearly reciprocated mainly by the eccentric rotational force of the crank shaft, Or a wedge bar is provided at the front of the hammer to crush the crushed material. However, since the hammer directly impacts the impact material to generate a striking force, the life of the equipment is greatly shortened due to the fatigue load.

Accordingly, when the crankshaft is rotated by the motor, the eccentric shaft is eccentrically moved, and the eccentric movement of the eccentric shaft is transmitted to the connecting rod to be converted into a linear reciprocating motion of the piston, And a technique in which the cylinder hits the bit mounting block by the impact force and is transmitted to the bit is preliminarily registered.

However, in the conventional art, there is a limit to an increase in the impact force due to the structural characteristics of the impact of the pneumatic pressure compressed by the piston linear reciprocating motion on the cylinder. In order to increase the impact force, the eccentric amount of the crankshaft is increased to expand the stroke of the piston, It is inevitable to increase the size of the entire size due to the need to form a large diameter, so that the piston stroke and the size are reduced together with the small-sized hosel such as the pipe cleaning, so that the high strength hitting force is not obtained.

Further, since the impact force is generated by compressing the air in the section corresponding to the stroke of the piston, the cylinder internal air pressure is gradually increased to limit the increase of the hitting force.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in view of the above problems, and it is an object of the present invention to provide a mechanical pneumatic hermetic device in which a high output pneumatic hitting force is generated in a lightweight small structure by a short stroke of a piston and a reduced eccentricity of a crankshaft.

In order to achieve this object, a feature of the present invention resides in a cylinder 10 divided into a main volume chamber 20 and an expansion volume chamber 20 'by a guide ring 11; Main and extension pistons 30 and 30 'respectively installed in the main and expansion volume chambers 20 and 20' and linearly reciprocated by the crankshaft 1 and the connecting rod 2; The rod tube 32 is formed with a flow path 32a through which the main and expansion volume chambers 20 and 20 'communicate while connecting the expansion piston 30 and 30' through the guide ring 11, ); And a weight piston (40) installed in the main volume chamber (20) and adapted to be linearly reciprocated by air pressure acting by the main and extension pistons (30) and (30 ') .

At this time, the intake port 21 is provided at one side of the section where the weight piston 40 is turned at the top dead center and moved to the bottom dead center so that outside air is supplied into the main volume chamber 20 in which the compressed air exists .

In addition, when the main and expansion pistons 30 and 30 'move to the bottom dead center, the compressed air in the expansion volume chamber 30' moves to the main chamber 20 through the flow path 32a, And the expansion piston 30 (30 ') compressing force acts simultaneously with the weight piston 40. [

In addition, when the main and expansion pistons 30 and 30 'are moved to the top dead center, the suction force generated in the expansion volume chamber 30' is connected to the main volume chamber 20 through the flow path 32a, And the suction force of the expansion piston (30) (30 ') simultaneously acts as the weight piston (40).

The crankshaft 1 is further provided with an extended eccentric shaft 4 extended by the crank wheel 3 and the extended eccentric shaft 4 is installed at an equiangular position 180 ° with the eccentric shaft of the connecting rod 2 And is provided with a canceling piston (50) for canceling the eccentric vibration force while being linearly reciprocated in the opposite direction to the main piston (30).

The offsetting piston (50) is characterized in that the joint portion (52) is provided at the end of the offset piston (50) so that the vibration transmitting means (54) including the shaking table for harvesting the crop can be detachably attached.

The striking rod 60 is disposed in front of the weight piston 40 so as to be interchangeable and transmits the striking force of the weight piston 40 and a hammer H or wedge W is provided at the end of the striking rod 60 .

According to the above construction and operation, in the present invention, the volume chamber of the cylinder is divided into two main chambers by the guide ring, and the two pistons, that is, the main piston and the expansion piston are operated by a single crankshaft and the connecting rod A high output pneumatic hitting force can be obtained even if the eccentric amount of the crankshaft is reduced due to the generation of a high pressure (for example, about twice the degree) compared to the air pressure generated in the conventional single piston stroke distance. As a result, the size of the crankshaft housing can be reduced, In particular, since the eccentric amount of the crankshaft is reduced, vibration reduction and high-speed operation can be performed during operation, thereby increasing the number of strikes per hour.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view of a mechanical pneumatic hammers according to an embodiment of the present invention; FIG.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a mechanical pneumatic hermetic compressor.
3 is a structural view showing a configuration of replacing a hitting rod of a mechanical pneumatic hammers according to an embodiment of the present invention.
4 is a view showing a canceling piston of a mechanical pneumatic hammers according to another embodiment of the present invention.
5 is a structural view showing an embodiment in which a vibration transmitting means is connected to an offset piston;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The present invention relates to a mechanical pneumatic hermetic compressor wherein the mechanical pneumatic hermetic compressor includes main and expansion volume chambers 20 and 20 'in order to generate a high output pneumatic hitting force in a lightweight small structure by a short stroke of the piston and a reduced eccentricity of the crankshaft, ), A main piston 30 (30 '), a rod tube 32, and a weight piston 40.

The cylinder 10 according to the present invention is provided so as to be divided into the main volume chamber 20 and the expansion volume chamber 20 'by the guide ring 11. [ The cylinder 10 has a volume chamber formed therein to generate a vacuum suction force and a pneumatic pressure by a linear reciprocating feed force of the main and expansion pistons 30 and 30 ' Are divided into two separate spaces by a guide ring (11) provided between the guide grooves (30 ').

At this time, the guide ring 11 is screwed to the inner circumferential surface of the cylinder 10, or in a form in which the guide rings 11 are fitted to the end portions of the cylinders 10, And a guide hole 11a is formed in the center of the guide ring 11 so that a rod tube 32 to be described later is inserted and is linearly reciprocated with the main piston 30 and 30 ' .

The main and expansion pistons 30 and 30 'according to the present invention are respectively installed in the main and expansion volume chambers 20 and 20' and are linearly reciprocated by the crankshaft 1 and the connecting rod 2 do. 1, the expansion piston 30 'is directly connected to the connecting rod 2 and is reciprocated within the expansion volume chamber 20', and the main piston 30 is connected to the expansion piston 30 'so that the linear reciprocating feed force of the connecting rod 2 is transmitted.

At this time, the rod tube 32 is inserted into the guide ring 11 to connect the main piston 30 and the main piston 30 ', and the main and expansion volume chambers 20 and 20' Is formed. 2, the rod piston 32 is inserted into the guide ring 11, and the expansion piston 30 'is connected to the upper side and the main piston 30 is connected to the lower side. At this time, the extension piston 30 And the other side of the flow path 32a is opened to the bottom surface of the main piston 30 through the lower end of the rod 32 so that the flow path 32a is connected to the flow path 32a, 32a so that the internal pneumatic pressure of the main expansion chambers 20, 20 'is shared.

The volume chamber of the cylinder 10 is divided into two main chambers 20 and 20 'by the guide ring 11 and the two volume chambers 2 and 3 are separated by the single crankshaft 1 and the connecting rod 2, The pistons, that is, the main-expansion pistons 30 and 30 'are operated in conjunction to generate a pressure higher than the pneumatic pressure generated at the conventional single piston stroke distance (for example, about twice).

Accordingly, even if the eccentric amount of the crankshaft 1 is reduced, a high-output pneumatic hitting force is generated, thereby making it possible to reduce the size of the shaft case in which the crankshaft 1 is provided. Vibration can be reduced and high-speed operation can be performed, thereby increasing the number of hits per hour.

The weight piston 40 according to the present invention is installed in the main volume chamber 20 and is adapted to be linearly reciprocated by air pressure acting by the main and extension pistons 30 and 30 '. The weight piston 40 is installed in the main volume chamber 20 as shown in FIGS. 1 and 2, and is located below the main piston 30 and reciprocates linearly from the top dead center to the bottom dead center by the air pressure.

At this time, the intake port 21 is provided at one side of the section where the weight piston 40 is changed from the top dead center to the bottom dead center so that outside air is supplied into the main volume chamber 20. The intake port 21 is configured to prevent the striking force of the weight piston 40 from being canceled by the suction force generated when the main and extension pistons 30 and 30 'are turned at the bottom dead center and moved to the top dead center. For details, please refer to the following.

That is, the main and expansion pistons 30 and 30 'are turned at the top dead center and moved to the bottom dead center, and the heavy piston 40 is moved to the bottom dead point by the compressed air in the main volume chamber 20, The distance between the main piston 30 and the weight piston 40 in consideration of the position of the weight piston 40 at the time when the expansion piston 30 or 30 'is turned at the bottom dead center and moved to the top dead center, A plurality of air intake openings (21) are formed in the volume chamber (20) so as to introduce outside air into the space.

Since the weight piston 40 flows through the intake port 21 and the outside air flows into the weight piston 40 at a time point when the main and extension pistons 30 and 30 'reach the bottom dead center and the compression force is no longer increased, When the external air is introduced through the intake port 21, the high-output striking force is generated without interference with the suction force of the main piston 30 (30 ') after the turning at the bottom dead center. As the inertial force to move to the bottom dead center is maximized, the hitting power is further increased.

After the weight piston 40 is moved to the bottom dead center and the striking rod 60 is struck, the striking rod 60 is turned by the repulsive force to move to the top dead center. At this time, The hitting force is generated by repeating the operation of accelerating by the suction force and moving to the top dead center and then moving to the bottom dead center.

In operation, when the main and expansion pistons 30 and 30 'are moved to the bottom dead center as shown in FIG. 2 (a), the compressed air in the expansion volume chamber 30' And the compression force of the main and extension pistons 30 and 30 'simultaneously acts as the weight piston 40 and the main and extension pistons 30 and 30' The suction force generated in the expansion volume chamber 30 'is connected to the main volume chamber 20 through the flow path 32a so that the suction force of the main and expansion pistons 30 and 30' .

The striking rod 60 is disposed in front of the weight piston 40 so as to be interchangeable and transmits the striking force of the weight piston 40 and a hammer H or wedge W is provided at the end of the striking rod 60 do. A multi-cap is interchangeably fastened to a lower portion of the cylinder 10 in which the weight piston 40 is installed and the striking rod 60 is disposed in a straight line with the conveying direction of the weight piston 40 in the multi-cap.

As shown in FIG. 3, a hitting rod 60 equipped with a hammer H is mounted and used in a hemming operation, and a hitting rod provided with a wedge W is used in a rock breaking operation. Alternatively, the hammer H or the wedge W may be provided at the end of the hitting rod 60 in a replaceable manner.

Figs. 4 to 5 are block diagrams showing canceling pistons of a mechanical pneumatic air horn according to another embodiment of the present invention.

4, the crankshaft 1 is further provided with an extended eccentric shaft 4 extended by the crank wheel 3, and the extended eccentric shaft 4 is located at an equiangular position 180 ° with the eccentric shaft of the connecting rod 2 And an offset piston 50 which is reciprocated linearly in the opposite direction to the main piston 30 to cancel the eccentric vibration force. The canceling piston 50 is linearly reciprocated within the auxiliary cylinder 51 and the auxiliary cylinder 51 is formed parallel to the cylinder 10 connected to one side of the shaft case 1a at an equiangular position of 180 °.

As a result, the eccentric vibration force is canceled by reciprocating in the opposite direction between the main piston 30 (30 ') and the offset piston 50 during eccentric motion of the crankshaft 1, and the fatigue is reduced have.

On the other hand, the auxiliary cylinder 51, in which the canceling piston 50 is accommodated, is provided so as to be openable and closable by a cap, and the cap is separated from the vibration transmitting means 54 described later.

5, the canceling piston 50 is provided with a joint portion 52 so that the vibration transmitting means 54 including the shaking table for harvesting the crop can be detachably attached to the end thereof. The vibration transmitting means 54 is rod-shaped and has a fastening portion formed at one end thereof to be fastened to the joint portion 52, and a fastening groove is formed at the other end thereof. When the crankshaft 1 is rotated with the vibration transmitting means coupled to the joint portion 52 of the canceling piston 50 and the vibration transmitting means is sandwiched by the juvenile water, the vibration transmitting means 54 ) Is used as a vibrating machine for shaking off the jujube while being reciprocated linearly. At this time, due to mutual reverse movement of the main and expansion pistons 30 and 30 ', self propelling power of the main body of the panty is reduced, .

10: Cylinders 20, 20 ': Main and expansion volume chambers
30, 30 ': main, extension piston 40: weight piston
50: offset piston 60: hitting rod

Claims (7)

A cylinder 10 divided into a main volume chamber 20 and an expansion volume chamber 20 'by a guide ring 11;
Main and extension pistons 30 and 30 'respectively installed in the main and expansion volume chambers 20 and 20' and linearly reciprocated by the crankshaft 1 and the connecting rod 2;
The rod tube 32 is formed with a flow path 32a through which the main and expansion volume chambers 20 and 20 'communicate while connecting the expansion piston 30 and 30' through the guide ring 11, );
The flow path 32a is opened to the upper end of the rod tube 32 so that one end thereof communicates with the expansion volume chamber 20 'and the other end thereof is connected to the main volume chamber 20 through the lower end of the rod tube 32 Is opened to the bottom surface of the main piston (30)
A weight piston 40 provided in the main volume chamber 20 and adapted to be linearly reciprocated by air pressure acting by the main and extension pistons 30 and 30 ';
When the main and expansion pistons 30 and 30 'move to the bottom dead center, the compressed air in the expansion volume chamber 30' moves to the main chamber 20 through the flow path 32a, (30, 30 ') compressive force acts simultaneously with the weight piston (40). The method according to claim 1,
Characterized in that the intake port (21) is provided at one side of the section where the weight piston (40) is turned at the top dead center and moved to the bottom dead center so that outside air is supplied into the main volume chamber (20) Mechanical pneumatic hinges. 3. The method according to claim 1 or 2,
When the main and expansion pistons 30 and 30 'move to the bottom dead center, the compressed air in the expansion volume chamber 30' moves to the main chamber 20 through the flow path 32a, (30) and (30 ') compressive forces act simultaneously as the weight piston (40). 3. The method according to claim 1 or 2,
When the main and expansion pistons 30 and 30 'move to the top dead center, the suction force generated in the expansion volume chamber 30' is connected to the main volume chamber 20 through the flow path 32a, (30) and (30 ') suction force simultaneously act as the weight piston (40). 3. The method according to claim 1 or 2,
The crankshaft 1 is further provided with an extended eccentric shaft 4 extended by the crank wheel 3 and the extended eccentric shaft 4 is provided at a position 180 ° equidistant from the eccentric shaft of the connecting rod 2, Characterized in that an offset piston (50) is provided which cancels the eccentric vibration force while linearly reciprocatingly reciprocatingly reciprocating the piston (30). 6. The method of claim 5,
Wherein the canceling piston (50) is provided with a joint portion (52) so that a vibration transmitting means (54) including a shaking table for harvesting the crop can be detachably attached to an end thereof. 3. The method according to claim 1 or 2,
A hitting rod 60 which is installed in front of the weight piston 40 so as to be interchangeable and transmits the hitting force of the weight piston 40 and a hammer H or a wedge W at the end of the hitting rod 60 Features mechanical pneumatic hinges.

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