JP4485352B2 - Hammering device - Google Patents

Description

Detailed Description of the Invention

  The present invention is a hammering or pile driving device, which is connected to a work machine, for example, a main body, and is fixed in the main body so that the stroke of the movable hammering mass is received and the stroke is driven into the ground. Or a stroke transmission member for transmitting to a pile to be pulled up from this or the like or a tool connected to the device, and a clamp is provided between the stroke transmission member and the pile, and the pile or tool is gripped by the clamp. The present invention relates to a hammering device.

  A device is known in the prior art from US Pat. No. 5,765,651, in particular for driving piles which are subjected to upward and downward striking movements by steam or pressurized water into the ground and withdrawing from them. The pipe to be driven into the ground is arranged to extend through the central hole of the mass. These are associated with a lump cylinder or the like to cause the lump movement and striking movement to occur in both directions in the lump. The striking surface of the mass hits ring-shaped counterparts that are wedged to remain positioned around the pipe, thereby transferring the stroke to the pipe.

  The disadvantages of the solution found in U.S. Pat. No. 5,765,651 are the low capacity, the small impact surface dimensions and the pipe gripping from its head and the pipe does not steer the mass movement When it is located inside the lump in a state, it is mentioned that proper control cannot be performed. Due to the moving cylinder structure with symmetrical movement in both directions, the velocity imparted to the mass is very low. This is because water or steam into the cylinder must always be directed through the valve during movement. Thus, even if pressurized steam is used, movement does not become fast. This is because the steam must be directed through the valve to the cylinder, where the pressure is low in the first stage due to the previous direction of motion. Also, the vibration is large due to the back-and-forth movement of the symmetric mass. The speed of the backward movement is as fast as the speed of the stroke movement. The backward movement must be stopped without a stroke, which causes an unfavorable vibration in the device. If the backward movement is still performed at a low speed by the valve, the striking frequency remains moderate.

  In order to solve the above-mentioned drawbacks, it is suitable for driving piles into the ground by hammering or pulling up piles, and it is possible to attach tools as crushing hammers, a new using movable mass that works with these tools A hammering device is provided. The hammering device of the present invention has a cylinder for moving the lump, and can guide the fluid pressure so as to act on the piston side of the cylinder on the primary side, and the lump can be moved backward by the cylinder. The body can perform hammering motion, and the fluid pressure introduced to the primary side can compress the gas on the secondary side of the cylinder to the desired pressure and can perform the hammering motion of the mass by the cylinder. It is characterized in that the hammering motion is performed by discharging the gas from the primary side of the cylinder.

  An advantage of the hammering device of the present invention is that the hammering energy can be easily adjusted to a desired value. Adjustment is also possible by remote control. The acceleration of the mass is optimal. No medium is introduced into the cylinder causing the striking movement, so that only the expansion of the high-pressure gas occurs in the cylinder during the backward movement, so that the movement is faster. The cylinder piston compresses the gas space to a small size and increases its pressure by the force of the primary liquid pressure, so that the inconvenient vibration of this device can be reduced. In the final stage of compression, it is easy to slow down the movement of the piston by valve control, and in the final stage of the backward movement, by slowing the backward movement due to this action, the time spent for this backward movement is almost It will not be long. A hammering tool can be easily attached to the clamping means instead of the pile.

In the following, the invention is disclosed with reference to the accompanying drawings.
FIG. 1 shows a hammering or pile driving device fixed to the boom head of an excavator, this attachment being effected by a fixing component 12 included in the hammering device. The hammering device has a body 1 in which a hammer gear is arranged by a damping / flexible element 3. The hammering machine has a mass 2 and a cylinder 8 for moving the mass. One end of the cylinder is fixed to the main body connecting beam 21, and the other end is fixed to the mass 2. A striking surface 18 for hammering the striking surface 19 of the opposing member 5 is provided at the other mass end. The counter member 5 has a clamping device 6 which works in a manner known per se by the wedge action, and this clamping device is in an interference fit around the pile 7. For example, the clamping device 6 can be opened or tightened by a hydraulic device, whereby the pile gripping condition can be easily changed, removed and fixed from the cabin.

  A steering pipe 9 is arranged between the parts 21 and 5 for controlling the movement of the mass 2 before and after. Medium is directed along line 14 to the primary side 20 of the cylinder. The purpose is to lift the mass after the stroke. The secondary side of the cylinder is filled with gas, and the pressurized fluid pushes the piston against the filled gas. The filling gas is, for example, nitrogen, and is compressed to a high pressure according to s, which is the travel distance of the piston. By means of the control unit 17 it is possible to determine in advance, for example, how much pressure is constraining the primary side during backward movement, and some pressure is also generated on the secondary side of the cylinder. The pressure can also be measured from the secondary side and information can be transmitted to the control unit 17. The pressurized fluid is led from the valve device 13 along the line 14 to the primary side. When the control unit 17 operates and opens the switching valve in the line 14, the mass starts a striking motion downward. In this case, the stroke length is adjusted by remote control at the control unit 17 by controlling the pressure line 14 or by the pressure measured from the secondary side. For example, a permanent magnet 11 is provided at a fixed portion of the cylinder 8, and a proximity switch 10 is provided inside the main body 1, so that the position of the mass backward movement can be detected by the position detector formed by these. It has become. By means of the control unit 17, it is possible to select how far (distance s) the mass is returned for the stroke. The pressure generated by hammering against the secondary side of the cylinder is determined based on the length of the return stroke. Referring to FIG. 3, the pressure P applied to the secondary side increases as the stroke becomes longer. The filling gas (for example, nitrogen) added in advance to the secondary side is in the state of Pe. Desired hammering energy is received by determining how far the mass is directed by the pressurized fluid. Otherwise, the pressure to be sent to the primary side will increase to its pressure value before stopping the mass backward movement. In order to create a stroke from the primary side 20, the outlet of the pressurized fluid is opened and the gas pressure on the secondary side pushes the piston 16 and then also the piston rod, while the mass 2 moves the same distance. . The impact energy is E.

上式において、Ａは、ピストン断面積である（一次側の対抗圧力は、公式中には示されていない）。

In the above equation, A is the piston cross-sectional area (primary counter pressure is not shown in the formula).

  When the preliminary pressure Pe is known, it is possible to determine the striking energy using the above formula and the function of FIG. 3, whereby the value of the distance s is found and the backward movement is adjusted as S.

  The position of the mass 2 is observed by the control unit 17 and is manipulated by the pressure in the detectors 10, 11 and the line 14, which is the pressure to be sent to the primary side 20, which is not a problem of stroke motion. If not, it is equal to the primary pressure. The pressure generally occurring on the primary side can be examined from line 14.

  The simplest stroke length adjustment (= hammering energy) is performed by moving the detector 10 on the surface of the body 1. When the valve reaches the magnet 11, it changes direction within the valve device 13. However, if the detector is not moved, it is advantageous to use a position detector. Such a detection and observation device is selected such that the distance of the part 11 with respect to the detector 10 is indicated in the unit 17 for the entire stroke distance in question by the detector 10. Inductive detectors, proximity switches or other position indicating detection devices known per se can be used.

  Alternatively, when the primary or secondary fluid pressure is detected and reaches the set pressure, the control unit 17 provides an impulse to the valve to change the flow direction with respect to the stroke. The pressure valve is most appropriately set by remote control from the cabin, and the stroke size can be easily selected for each situation.

  FIG. 2 shows the hammering device in another way, for example in an excavator boom, rotated 180 °, whereby the pile is lifted from the ground by hammering. Steering using one clamp member and clamp component device 6 is possible. With the excavator boom, it is possible to maintain the prestressing pressure on the pile by lifting the hammering device upwards with an appropriate force by the boom. Similarly, a downward preliminary pressure is maintained as the pile is driven into the ground by hammering. The pre-pressure is conveyed by damping rubbers 3, 4 and its size must be limited to avoid rubber leaks.

  When it is necessary to increase the stroke, it is possible to provide the movable mass 17 inside the mass 2 and to provide a movable space larger than the volume required by the mass 17 for this purpose. For example, the distance of the mass 17 is d, and the mass hits the end of the space after making a stroke. This collision occurs with a slight delay with respect to the collision between the mass 2 and the opposing product 5. Due to the double stroke, the stroke effect of the mass is increased. The mass 17 may be in the form of a solid, may be a liquid, or may be a heavy particle. Double strokes occur in devices that perform both downward and upward hammering actions.

  1 and 2, the cylinders 8 are located outside the mass, these cylinders may also be located near the steering pipe 9, and their other end is at the end of the mass 2. It is fixed. In this case, the device is clearly smaller with respect to its diameter if the body 1 is, for example, a pipe. Of course, the structural height is low.

It is sectional drawing of the apparatus seen from one side which drives a pile into the ground by hammering. It is sectional drawing of the apparatus seen from one side part which pulls up a pile from the ground by hammering. It is a figure which shows the state of the increase in the pressure added to the secondary side of a cylinder as a function of a piston. It is a figure which shows the 2nd lump which moves inside a piston.

Claims (7)

A body (1) capable of connecting the hammering device to a work machine ,
Is fixed to the main body (1), pile being pulled stroke receives the stroke of the movable hammering masses (2) from which or ground driven into the ground (7), or hammering tool coupled to the hammering device A stroke transmission member (5) for transmitting to
A clamp (6) is provided between the stroke transmission member (5) and the pile (7) or the hammering tool, and the pile (7) or the hammering tool is gripped by the clamp, and the stroke transmission member ( 5) and the hammer ring masses (2) is ring-shaped, piles are hammering (7), the hammering device is arranged to pass through the ring-shaped masses,
The hammering device has a cylinder (8) that is arranged outside the ring-shaped mass and moves the ring-shaped mass (2),
The ring-like mass (2) can be retracted by the cylinder by directing fluid pressure to act on the piston (6) of the cylinder on the primary side (20) ,
Can be a hammering movement in the ring-shaped masses (2) is compressed to the desired pressure of the secondary side of the gas cylinder by the fluid pressure guided to the primary side (20) (8) cylinders,
The hammering motion is performed by discharging the fluid pressure from the primary side (20) of the cylinder (8) ,
The hammering device has a pipe (9) that extends through the central hole of the ring-shaped mass (2) and steers the ring-shaped mass (2).
A hammering device characterized by that . Cylinder (8), these and the other end portion is fixed to a ring-shaped masses (2),
The hammering device according to claim 1. Hammering energy of the ring-shaped masses (2) can be adjusted by the length of the retracting movement of the ring-shaped masses (2),
The hammering device according to claim 1. Hammering energy of the ring-shaped masses (2) can be adjusted by adjusting the pressure of the secondary side of the cylinder (8) (p),
The hammering device according to claim 1. Additional masses against ring masses (2) (17) is positioned so as to distance (d) moving relative to the ring masses (2), with respect to the stroke transmission member of masses (17) (5) hammering impact, stroke delayed performed than the distance (d) ring-shaped masses due to (2),
The hammering device according to claim 1. The device can be rotated 180 ° to drive a pile into and out of the ground,
The hammering device according to claim 1. The device comprises a control unit (17), can adjust the hammering energy of the ring-shaped masses (2) by the control unit by remote control,
The hammering device according to claim 1.

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