SE524084C2 - Vibrator plate, has vibrating part with pair of eccentric axles driven by separate hydraulic motors - Google Patents

Abstract

The vibrating part is provided with two eccentric axles (4, 5) each driven by its own hydraulic motor (7, 8). The axles are located on either side of the centre of gravity for the vibrating part and rotate independently from each other. The flow of hydraulic fluid to the motor is regulated by a valve. As the plate is moved backwards and forwards, energy from the previously driven axle is used to acceleration rotation of the hydraulic motor being used to provide the drive force for moving the plate.

Description

: t:: - - - - “I _: - '.:; r - - - - '' ° H - I. f'f "” 'u. a - .. .. .a k .. - aa 3 The eccentric axis, which rotates in the direction of the plate, gives a circular movement of the vibrating part By cooperating with the ground, the plate moves forward at the same time as it generates pressure shocks against the ground surface.

The known reciprocating plates have an eccentric element with two eccentric axes as close to the center of gravity of the vibrating part as possible, the eccentric axes are counter-rotating and rotate synchronously. Through the counter-rotation, during a rotation of a revolution, a linear resultant movement of the vibrating part is obtained and through cooperation with the substrate, a displacement of the plate and pressure shocks against the substrate are obtained. In order for the plate to move in the desired way, the linear movement resultant must have an angle to the ground surface of approximately 30 degrees. In order to achieve the reciprocating movement of the plates, the relative angle between the eccentric axes can be changed, during operation, meaning that the linear direction of movement of the vibrating part can be varied either steplessly or between two fixed angles.

In the case of stepless regulation, the directional movement of the vibrating part can be e.g. also perpendicular to the surface, but the plate will not surface then.

There is also a design with counter-rotating eccentrics rotating around an axis.

The eccentric shafts can be driven with V-belts from a drive motor or be hydraulic drive.

The disadvantage of these designs of reciprocating vibrator plates is that the packing ability and passability are not particularly good and that both the packing ability and the passability decrease as the filling material becomes more grainy.

In some countries with little access to pronounced fi iction material, such as tulle material, reciprocating vibrator plates are therefore used almost not at all but only advancing plates.

The reason for the relatively low packing effect with known front and back plates is the fl linear movement of the vibrating part, which means that the vertical movement component becomes relatively small. - t ... . , '_' _ _ '_10. n "a.. aa. f.,,, _ '' * ß.. .i, U z - u. ..., _ _ _ _ _, _.. .. -... -. a. n 4 The fact that the vertical movement component becomes small means that the impact pressure against the substrate becomes low, which results in a low packing effect, especially on incoming filling materials.

The vertical movement component is also important for the passability of the reciprocating plates as it is the vertical movement component that lifts the vibrating part from the depression in the filling material that the plate itself creates, with more accessible material and with material with lower elasticity the passability decreases with a low vertical movement component. .

Another disadvantage of these reciprocating vibrator plates with two counter-rotating eccentric axes is that they form a pair of forces, at the forward and reverse positions of the eccentric axes, which give rise to a moment which rotates the vibrating part about a symmetry axis between the eccentric axes. The torque varies with the relative angle between the eccentric axes and the resultant's set angular position and is zero when the weights are in position for fi am or reverse and the relative angle between the eccentric weights is zero and max at 90 degrees relative angle between the eccentric weights.

This resulting movement of the slab means that it has poorer passability as the slab digs into the substrate.

Another disadvantage of these known reciprocating vibrator plates is that the eccentric elements with gears for synchronous speeds between the eccentric axes and the mechanism for adjusting the relative angle of the eccentric axes during drive fi are complicated and thus expensive. The object of the invention is to solve the above disadvantages of known reciprocating vibrator plates.

The invention is a solution to these problems in that the vibrational movement of the vibrating part of the plate does not consist of a linear movement, with an flac angle to the ground, but has the form of a circular movement during a rotation of the eccentric axis. This is accomplished by driving only one eccentric shaft at a time in 524 084 '5. Furthermore, the amplitude varies in the longitudinal direction of the bottom plate with the greatest amplitude at the end towards the direction of movement, where the vertical amplitude is significantly greater with this invention than with known front and back plates. The horizontal amplitude of the bottom plate is also larger with this invention than the known front and back plates. The comparisons are of course made with corresponding sizes and vibration data between known reciprocating plates and the winding.

Furthermore, no force is generated which tilts the base plate during the rotation of the eccentric shaft when only one shaft is set in rotation.

The invention also provides a more cost-effective solution of the changeover process between reciprocating the vibrating plate than known embodiments as no synchronization between the eccentric axes is required and no mechanism is required around the eccentric axes to effect a change of direction of movement.

The invention will be described in the following, with reference to the accompanying drawings, Fig. A, Fig. B, Fig. C, Fig. D, Fig. E, Fig. F and Fig. G.

The vibrator plate according to the invention, seen from the side in Fig. A, consists of a vibrating part (1), a stripped part (2) and handles (3) of the main components of the vibrating part, as shown in Fig. B and Fig. C where FigC shows a section through the center of the eccentric shafts, where a base plate (33) with two eccentric elements (34) are connected to the base plate. Each eccentric element consists of a housing and bearing of a rotatable eccentric shaft (4,5) with the center of rotation perpendicular to the longitudinal direction of the plate. The longitudinal direction of the plate is the direction in the directions of movement of the plate and the width of the plate is perpendicular to the longitudinal direction. The eccentric shafts (4,5) consist of a shaft with an eccentrically placed weight connected to the shaft.

The vibrator plate also consists of a stripped part connected to the vibrating part by a number of vibration isolators. The stripped part is in principle a bed for an internal combustion or electric motor with hydraulic fuel and that it supports a hydraulic tank, battery and other equipment and is a fastening of handles for controlling the plate. The eccentric alternator with the rotatable eccentric shafts (4,5) without synchronized speed ratios are placed symmetrically, in the longitudinal direction of the plate, around the center of gravity of the vibrating part (6) with the center of rotation of the axes perpendicular to the longitudinal direction of the plate.

Both eccentric shafts are connected to each hydraulic drive motor (7,8) which alternatively drives one or the other of the eccentric shafts. The direction of rotation of the eccentric axes is in the direction of travel of the plate, which means that the eccentric, during the rotation of a revolution, successively passes the positions: Vertically downwards, horizontally to the line of symmetry of the vibrating part, vertically upwards, horizontally in the direction of travel, vertically downwards.

By this embodiment, the vertical amplitude varies along the bottom plate and is greatest at the end of the driving part where the movement during a rotation of a revolution describes a circle-like shape. This gives, in comparison with now known front and back plates, a significantly larger vertical amplitude and horizontal amplitude at the end of the driving part, which gives a high packing effect even in granular filling materials and good passability in materials with low elasticity. tilts the vibrating part.

In order to increase the dynamic pressure against the substrate and thereby further improve the packing effect, in a design of the invention, as shown in Figs. width but only over part of its length. The abutment surface of the base plate against the ground in its front and rear areas has the same level. The plate for fl moves in the direction where an eccentric axis rotates, ie. if the front eccentric shaft rotates, the plate moves forward and if the rear eccentric axis rotates, the plate moves backwards. 0 o an. . v q. . . f a "." ~: _ .. v .-: n-. . . a. . . _: ': n ¿_, "' '0 ø uaa. r., _;: - a... is built with a hydraulic pump (28) driven by an internal combustion engine or electric motor which normally rotates at a constant speed, the speed can, however, be varied by the operator of the plate to eg idle speed of the internal combustion engine. The hydraulic system is a constant flow system, with a directional valve (9) directing the hydraulic fluid to one or the other of the hydraulic motors (7,8) driving the eccentric shafts. The directional valve can be electrically, mechanically or hydraulically operated, the directional valve has fi venous return to the neutral position, which means that when starting the dry combustion engine or the electric motor, none of the hydraulics rotates the motors, furthermore the plate operator handle (3) is provided with so-called deadman grip, which means that if the operator releases the grip, the current, alternatively control pressure or mechanical force, is broken until the directional valve and demia go to the neutral position and the plate stops quickly.

The hydraulic system also has a hydraulic tank (l1), as well as a piping system and other necessary standard details in the hydraulic system such as terlter, tank hatch open or closed, overflow valve, the standard details are not shown in Fig.D.

Thus, when changing the direction of movement of the plate, the hydraulic fluid fate changes from one hydraulic motor to the other hydraulic motor, which is to accelerate the stationary eccentric shaft to the plate's drive frequency in a very short time, while the eccentric shaft and hydraulic motor must stop rotating.

This process must take place so quickly that it has no practical significance for the packing work.

To avoid using an internal combustion engine or electric motor with greater power than the continuous operation requires and to ensure that the internal combustion engine speed does not decrease significantly when changing the direction of plate movement, the rotational energy is used in the eccentric shaft turned off to help drive the hydraulic pump. This is done by the outlet lines (13,14) of the hydraulic motors being connected to a closed tank line (10) to which the suction line (12) of the pump is also connected. The closed tank line may be formed with two connections to the tank or be designed as a loop with a connection to the tank, as shown in Fig.D. The outlet lines of the hydraulic motors are connected to the closed tank line on each side of the pump suction line connection to the tank line. In the closed tank line between the suction line of the pump and the outlet lines of the hydraulic motors, two non-return valves (15, 16) are installed with the reverse direction towards the hydraulic tank (1 1). Furthermore, in the tank line on the opposite side to the non-return valves if the hydraulic motor outlet lines are installed, two pressure-controlled non-return valves (17, 18) with reverse direction to hydraulic tank and with the control pressure lines (19,20) for opening in the reverse directions on the opposite side of the pump suction line in the line parts between non-return valve and pressure-controlled non-return valve.

In the supply lines (21,22) of the hydraulic motors between the directional valve and the inlet ports of the hydraulic motors, lines (23,24) are connected to the hydraulic tank, in these lines a non-return valve (25,26) is installed with a reversing function against the hydraulic tank.

At start-up, of the hydraulic system, the directional valve is in the middle position, whereby the hydraulic pump sucks hydraulic fluid from the tank and via the directional valve the hydraulic fluid returns to the tank line.

During continuous operation of a hydraulic motor, the hydraulic fluid circulates through the pump to one of the hydraulic motors and back to the tank line and the suction side of the pump.

The turnover of the hydraulic fluid in the system consists of the amount of leakage fluid that leaks from the motors and the pump, this leakage fluid goes directly to the tank via the pipes (42,43, 44). The pump sucks the corresponding amount of hydraulic fluid from the tank through the non-return valves and the pressure-controlled non-return valves, this amount of hydraulic fluid is sufficient circulation of the hydraulic fluid.

When shifting rotation from one eccentric shaft to the other eccentric shaft, this is done as previously stated by the directional valve changing the hydraulic fluid flow from one hydraulic motor to the other hydraulic motor.

The eccentric shaft which becomes without drive continues for a short time to rotate through its accumulated rotational energy. In the event that the hydraulic motor (7) is switched off and that. _ '_: '00 2' c Yes. nu: N _ u - .- - a,,,. 4 0 ß .n ... _ _. _ _ _ _ _: -; ~ - ~ -. . . . .I .. ... i. n ._ 9 hydraulic motor (8) is switched on and must be accelerated up to speed, then the hydraulic motor (7) will briefly function as a pump and suck hydraulic fluid from the tank via line (23). Via the hydraulic motor outlet line (13), a pressure builds up between the pressure-controlled non-return valve (17) and the non-return valve (16). This means that the pressure difference between the suction side and the pressure side of the pump (28) decreases and the pump learns an addition of power, this happens when the pump speed drops so much that the suction output from the pump is less than the output generated by the rolling hydraulic motor (7).

The return flow from the driven hydraulic motor (8) goes to the tank via the pressure-controlled non-return valve (18) as long as the pressure generated from the rolling hydraulic motor (7) exceeds the return pressure from the driven hydraulic motor (8).

A corresponding process takes place if instead the hydraulic motor (8) is switched off and becomes unrolling and the hydraulic motor (7) is driven and is to be accelerated up in speed, the process and designations are shown in Fig.D.

Instead of lines between the valves, the system can be provided with one or more hydraulic blocks where the lines are replaced with ducts and the valves are integrated in the hydraulic block.

Another embodiment of the invention's hydraulic system is shown in F i g.E. The system is a constant flow system with a pump (28) that sucks hydraulic fluid from the tank and via a directional valve (9) distributes the hydraulic fluid to one or the other hydraulic motor (7,8). To each hydraulic motor inlet line (36,37) and outlet line (38,39) a bypass (29,30) is connected and in these bypasses non-return valves (3 1,32) are installed with reverse direction to tank.

The design meant that when shifting operation from one hydraulic motor to the other hydraulic motor, the shut-off hydraulic motor rotates until the accumulated rotational energy of the eccentric shaft has run out by the hydraulic motor sucking hydraulic fluid from the hydraulic motor outlet line, which is connected to tank, in addition to flow and frictional resistance does not occur. 524 084 10 This has the effect that with very frequent recurrent forward and reverse maneuvers of the plate, the rotational speed of the eccentric shaft need not be accelerated as much as if the shut-off hydraulic motor had been braked by the hydraulic fluid flow being throttled or switched off completely. This means that the reduction of the vibration frequency during frequently recurring reciprocating maneuvers is limited, which can occur if the internal combustion engine is overloaded and its speed thereby decreases.

The design also meant reduced stresses on the components.

The process of very frequent front and back maneuvers is not normally done with a front and back plate, but the design of the plate allows it to be done.

The vibrator plate according to the invention, with the design of the hydraulic system according to Fi gD, includes a so-called deadlock grip, which means that if the operator releases the grip on the operator handle, the vibrator plate stops its movement forwards or backwards. to the directional valve (9) it then sets itself in neutral position whereby the plate stops quickly by recirculating the constant flow of the hydraulic fluid from the pump (28) to the tank line (10) or directly to the suction line of the pump (12) the pressure and fate of hydraulic fluid the shut-off hydraulic motor is (8), and which is generated due to the rotational energy from its eccentric shaft becomes trapped between the non-return valve (15) and the pressure-controlled non-return valve (18) this means that the hydraulic motor (8) which is three .

Claims (5)

524 084: .._, .._ =. I .. 'Z.'Z 222 Ü. . 1 1 Patent claim. A reciprocating vibrator plate, characterized in that the vibrating part (1) is provided with two separate rotatable center axes (4, 5) without synchronized rotational relations between them with the center of rotation placed on each side in the longitudinal direction of the plate about the center of gravity of the vibrating part (6) with the axis of rotation of the axles perpendicular to the longitudinal direction of the plate and that both eccentric axes are connected to separate hydraulic drive motors (7, 8) which effect rotation of one or the other of the eccentric axes by a directional valve (9) controlling the hydraulic fluid. The reciprocating vibrator plate according to claim 1, characterized in that the bottom surface of the bottom plate (33) has a bulge over the entire width of the bottom plate and over a part of the length of the bottom plate. Reciprocating vibrator plate according to Claim 1, characterized in that the hydraulic system has a tank line (10) with closed tension to the hydraulic tank (11) and that a suction line (12) is connected to the pump and that on each side of this pump suction line the outlet lines (13,14) from the hydraulic motors are connected and that in the tank line in the spaces between the pump suction line and the hydraulic motor outlet lines two non-return valves (l5, l6) are installed with reverse function against hydraulic tank and that in the tank line opposite the non-return valves the hydraulic motor outlet lines are two pressure-controlled non-return valves (17,18) installed with reverse function against hydraulic tank and with the control pressure lines (19,20) for opening in the reverse direction connected to the tank line opposite the pump suction line in each line part between non-return valve and pressure-controlled non-return valve and in the supply lines (2l, 22) to the hydraulic motors are lines (23,24) to hydr aultank connected and that in these lines each non-return valve (25,26) is installed with a non-return function against the hydraulic tank. 524 084:; '; "=:.;' :; °: - 12 4. A reciprocating vibrator plate according to claim 1, characterized in that the supply lines (36,37) and outlet lines (38,39) of the hydraulic motors are connected to each line (29,30) and that in these lines there is each a non-return valve (31, 32), installed with reverse function against the outlet pipes. The reciprocating vibrator plate according to claim 3 or 4, characterized in that the directional valve (9) of the hydraulic system in neutral position has a channel connecting the outlet line of the pump (28) to the return line (27) and that the outlet channels of the directional valve to the hydraulic motors (7,8) years closed.