SE461572B - vibration device - Google Patents

Description

10 15 20 25 30 35 40 461 572 displacement linearly, which thus greatly facilitates and simplifies control.

A preferred embodiment of the invention is described in more detail below with reference to the accompanying drawings, in which Fig. 1 shows a side view of a vibration feeder according to the invention; Fig. 2 shows on a larger scale a cross section of a of the two wheel-like members attached to the motor shaft; Fig. 3 shows a part of Fig. Z illustrating the moving weight in a changed position.

Pig. 1 shows a vibration feeder 10 similar to that of patent U.S. Pat. No. 3,358,815 and which comprises a material supporting means in the form of a trough 11 arranged on insulating springs 12, which are supported by upright supports 13 from a base 14.

The vibration generating device comprises a vibrator, which in its entirety is denoted by 15 and has an electric motor 16, which runs at a constant speed. The electric motor is connected to a bracket 17, which is attached to the trough 11 via rubber shear springs 18. The motor 16 is thus connected to the fitting 17 via a spring device and the motor runs at a constant speed close to the natural frequency then of the spring device.

The motor 16 has a motor shaft 20, which is shown in Fig. 2 dashed line and at each end bears a wheel-like means 21, one of which is shown and the other is identical performed. On each wheel on one side of the axis of rotation of the axle 20 is attach a fixed weight 22. A cylinder is further arranged on each wheel 23, which extends radially on either side of the shaft 20. The cylinder has one end 24 near the center of gravity 22 of the weight 22 and the opposite end on the other side of the axis of rotation of the shaft. The end 24 of the cylinder is closed by means of a lid 26, to which a coil spring 27 is attached.

Inside the cylinder 23, a weight 28 is attached to a displacement in the cylinder. bar piston 29. The piston and the weight together form a moving weight inside the cylinder 23.

The lid 30 closes the end of the cylinder ZS, so that it is formed a pressure chamber 31 between the piston 29 and the lid 30. A pressure fluid line 32 is connected at one end to the pressure chamber 31 and at the other end with a rotatable connector 33, which is used mounted on the shaft 20, as shown in Fig. 1. A pressure fluid line 34 is connected at one end to the connector 33 and to it the other end connected to a source of pressure fluid, e.g. compressed air.

The center of gravity of the piston (shown at 35) and the weight system plus I: - 10 15 20 25 30 35 40 3 461. 572-. the portion of the spring 36 which is located to the right of the shaft seen in Fig. 2 is in the idle state in the position shown. After commissioning and when the engine is running at the intended speed, the piston and the weight are moved outwards from the axis of rotation to the position as shown in Fig. 3. By the rotation, the spring 27 is stretched and exerts a pulling force, which counteracts that applied to the piston and weight centrifugal force. In the position of the components, as shown in Fig. 3, is the vibrational force generated by the fixed weight 22 and the spring portion to the left of the axis of rotation (seen in Fig. 3), equal to and opposite to the vibration force generated by the weight, the piston and the spring portion 36 to the right of the axis of rotation, which as a result of which the trough 11 is not imparted to any vibrating force by means of the pulsator. When fluid pressure is applied to the pressure the chamber 31 through the conduit 34, the connector 33 and the conduit 32, bring the piston and weight to the left (seen in Fig. 3), the spring tension initially amplifying it force exerted by the pressure fluid, but the spring action decreases hand, when the piston and weight are moved towards the axis of rotation (thus reduces the centrifugal force exerted on these components), and finally, when the piston and cylinder have been moved further further to the left beyond the position shown in Fig. 2 counteracts the coil spring further movement of the piston and the weight, which then moved to the left by a combination of the fluid pressure and centrifugal force.

When the centrifugal force, which is generated by the moving weight and the piston, is largest, as shown in Fig. 3, and sufficient for to move the weight and the spring to that shown in said figure position against the action of the spring tension, the spring the voltage to assist the fluid pressure in the movement of the spring and the weight to the left, thereby reducing the participation of the spring zero, when the piston and the weight reach the position shown in Fig. 2, and the spring is then compressed and acts in the opposite direction against the fluid pressure, as the piston and weight move further to the left of the position shown in Fig. 2, which movement of the piston and cylinder generates a centrifugal force, which strives to move them outwards towards the fixed weight 22.

It is especially advantageous to use a coil spring in the arrangement shown, since the abbreviation and the elongation of a helical spring is directly proportional to the force, i.e. the relationship is linear. This linear relationship contributes 461 572 to make the control of the vibration generated by the device simple and accurate.

Claims (8)

10 15 20 25 30 35 40 Patent claim Device for varying the vibrational force generated by a rotating mass, characterized in that it comprises a rotatable shaft (20), a weight (22) fixed to the shaft (20) with its center of gravity offset from the center of rotation of the shaft (20). , a carrier (23) attached to the shaft (20) and extending radially thereto on both sides of the center of rotation of the shaft (20), a second weight (28) movably received by the carrier (23), and tension and compression spring means ( 27) fixed at opposite ends (24, 25) of the carrier (23) and against the second weight (28) and placing the second weight (28) in a first position on one side of the center of rotation of the shaft (20) and means ( 29) to move the second weight (28) from the first position towards a second position on the other side of the center of rotation of the shaft (20). Device according to claim 1, characterized in that the carrier (23) has an elongate shaft extending radially on both sides of the center of rotation of the shaft (20), the shaft of the carrier (23) passing through the center of gravity of the weight (22) which is fixed in relation to the shaft (20). Device according to claim 2, characterized in that when the second weight (28) is on the same side of the shaft (20) as the fixed weight (22), the second weight (28) increases the vibration force, and when the second weight (28) is on the opposite side of the shaft (20) from the fixed weight (22), then the second weight (28) reduces the vibrational force generated by the rotating mass. Device according to claim 1, characterized in that the center of gravity of the fixed weight (22) is on the opposite side of the axis (20) of the axis of rotation in relation to the center of gravity of the second weight (28). Device according to claim 1, characterized in that the carrier is a cylinder (23). Device according to claim 5, characterized in that the means (29) for moving the movable weight (28) comprises fluid pressure corresponding means (29) in the cylinder (23) and resting against the side of the movable second weight (28) opposite to the spring means (27) for moving the movable weight (28) from the position on one side of the center of rotation of the shaft (20) towards a position on the other side of the center of rotation of the shaft (20) and connecting means (32) the fluid pressure response means (29) having a source of fluid pressure to vary the force generated by the device. '. Device according to claim 1, characterized in that the spring means (27) moves the movable second weight (28) to a position with its center of gravity on the opposite side of the center of rotation of the shaft (20) when the shaft is at rest, the spring means ( 27) supports but does not prevent movement of the movable weight (28) to the opposite end of the carrier (23) when the shaft (20) is rotated and wherein the means (29) for moving the movable weight (28) is activated to move the movable weight. set the weight (28) to a selected position relative to the fixed weight (22) to vary the vibrational force generated by the rotating mass. Device according to claim 1, characterized in that the tensile compression spring (27) places the center of gravity of the movable weight (28) on the other side of the center of rotation of the shaft (20) from the fixed weight (22) when the device is at rest, and wherein the spring (27) with traction acts against but does not prevent movement of the movable weight (28) outwards from the center of rotation of the shaft (20) when the shaft is rotated, that a piston (29) in the carrier (23) is fixed at the movable weight (28), and wherein the means for displacing the movable weight (28) is fluid pressure in the carrier (23) acting against the piston (29) and the spring (27) for displacing the movable weight (28) by by means of the traction force of the spring (27) in a direction towards the rest position and then past the rest position and past the center of rotation of the shaft (20) against the compressive force of the spring (27) to increase the vibrational force generated by the rotating mass.