SE438280B - VIBRATION DUMPING HANDLE - Google Patents

Description

More specifically, a device is provided with a vibration-damping handle for a work machine, which in operation generates vibrations and which handle is intended to be attached to a pin connected to the housing of the machine by means of a sleeve element in the form of a rubber holding cylinder, the length of which is less than the length of the handle. What is new for this device consists in that the sleeve element with its inner surface is directly or indirectly fixedly connected to the shaft pin and with its outer surface is directly or indirectly fixedly connected to the inner cylindrical surface of the handle and has such an axial length that the torque point area in the sleeve element, within which in the application of forces to the handle change takes place from a compressive stress to a tensile stress lies between the machine housing and the center of the handle and that the sleeve element has such thickness and rigidity that the handle is allowed to pivot at an angle on either side of a central reference line. the pressure force applied to the handle and the work machine and the dynamic vibration force of the work machine.

The sleeve element, which preferably consists of a cylindrical tube of rubber, is suitably vulcanized to an inner steel tube, which in turn is firmly anchored to the shaft journal of the machine and has an outer steel tube, at which the cylindrical shell surface is vulcanized, which outer steel tube in its turn is firmly connected to the inner, cylindrical wall of the handle. However, it is also possible in time to directly vulcanize the rubber sleeve on the shaft pin and the cylindrical wall of the handle, respectively.

As will be described later, the rubber element will act as a universal joint, in which the property of the rubber is more easily stretched than compressed at a given applied force, the amplitude of vibrations and shocks from the machine being substantially equalized and thus not affecting the handle.

The invention is described in connection with the accompanying drawings in which figure 1 very simply shows a working machine, for example a percussion drill with two handles, figure 2 schematically shows a device according to the invention with unloaded handle, figure 3 shows a handle with a damping sleeve element according to the invention, figure H shows the device according to figure 3 when applying a compressive force to the handle, figure 5 shows the device according to figure U when an impact force is generated by the machine and figure 5 shows a comparison between the invention and known handles.

The percussion drill machine 1 shown in simplified form in Figure 1 has a machine housing 2 containing, for example, a pneumatic drive motor, which drives a percussion drill 3. The machine housing 2 has two fixed, projecting shaft pins H and 5, respectively, which here are intended to be coaxial and diametrically opposite each other. The shaft journals U, 5 can, however, form an angle with each other and do not have to be diametrically opposite. A vibration-damping handle 6 and 7, respectively, is mounted on each shaft pin. Figure 2 illustrates in more detail one handle 7, which is identical to the handle 6.

The end portion 8 of the handle 7 facing the machine 1 has a bore with a cylindrical inner wall 9, into which a cylindrical, damping element 10, consisting of rubber, is inserted. On the outer cylindrical circumferential surface of the damping element 10 is vulcanized a tube 11 of steel or other suitable metal with in the embodiment shown substantially the same axial length as the element 10.

The inner cylindrical surface of the tube 11 may be fixedly connected to the outer surface of the rubber element 10 in any other suitable manner, for example be glued. The inner cylindrical surface of the rubber element 10 is correspondingly connected to the outer surface of a cylindrical metal tube 12, which has an inner cylindrical bore adapted to the pin 5 so that a fixed connection can be established. The inner cylindrical wall of the tube 12 can for instance be dimensioned so that the tube can be pressed onto the cylindrical shaft pin 5, but the fixed connection can also consist of, for example, a threaded connection. In the embodiment shown, the outer part 13 of the handle 7 facing away from the machine 1 is tubular and has a smaller diameter than the end portion 8. As shown in Fig. 2, the connection between the end portion 8 and the tube 11 has been effected by means of screws 1a. _..__......__............_..._......_..___._ ,. .__ * Poon QUALITY aso22s1-4- 4 The function of the new device is now described in connection with figures U and 5. Figure 5 illustrates the handle when the machine's work tool 3 is applied to the surface to be cured and the operator exercises a certain compressive force FS on the two handles 6 and 7.tkmdtaget 7 and of course also the handle 6 will then swing in the direction of the force FS and form an angle CK near the center line A of the shaft pin 5. It has here been assumed that the handle 7 is straight and coaxial with the shaft pin 5 , but in the case the handle part 13 is designed in a special way conditioned by ergonometric points of view, which means that the handle 7 and the shaft pin 5 do not have a common center line, the reference line A is attributed instead to the shaft pin 5 and the rubber sleeve 10 center line, which coincides with the shaft the center line of the pin. During this deflection of the handle, which here is intended to take place in a vertical plane, the rubber material will be subjected to tensile and compressive stresses, respectively. The tensile stresses have been marked with a minus sign and the compressive stresses with a plus sign. The stresses in the rubber material change characters approximately within a range mp, torque point. When the machine is started, vibrations, dynamic forces, Fd with the amplitude 7 \ occur. This dynamic force Fd causes a compression of the rubber material within the area B, but because an elongation requires less force than a compression, a much greater elongation or increase of the tensile stress is obtained within the area C. At the opposite end of the rubber sleeve 10, i.e. the end closest to the machine, the fdynamic force a decrease of the compressive stress and a decrease of the tensile stress ie the mp range is shifted as shown.

This all results in the handle 7 being displaced upwards depending on the dynamic force, but at the same time the angle OC increases correspondingly and with the correct dimensioning of the rubber damper thickness, length and the stiffness of the rubber material so that the rubber damper allows a swing within an angular range. of the static compressive force FS and the dynamic compressive force F1, the outer end l5 will always be substantially still, ie vibrations are not transmitted to the end point. Of course, the damping effect will decrease the closer the machine is to the hand, but the damping effect will be calculated according to the entire length of the handle completely satisfactorily. Figure ü illustrates the damping function of a conventional handle with a rubber sleeve along the entire length of the handle (upper curve) and a handle according to the invention with the dimensions given below (lower curve). After the y-axis the dynamic force expressed in the acceleration m / S2 is given and after the x-axis the vibration frequency is given.

The device according to the invention consisted of a handle 7 with a total length of 165 mm, a rubber sleeve 10 with a length of 35 mm, an inner diameter of 25 mm, an outer diameter of H0 mm and tubes 11 and 12 (Fig. 2) with a wall thickness of 2 mm. The comparison handle (upper curve) was provided with a rubber damper of corresponding construction with a total length of 165 mm and the shaft journal in this case extended through the entire handle and the rubber damper. The area between the two curves corresponds to the energy absorbed by the device according to the invention.

Practical tests have shown that the length of the rubber damper, depending on the vibration forces and vibration amplitudes generated by the machine, should be between 20-H0% of the total length of the handle.

FOR QUALITY

Claims (3)

sso22s1-4 P A T E N f K R A V Device for a vibration-damping handle (7) for a work machine (1), which in operation generates vibrations and which handle is intended to be attached to a pin (U, 5) connected to the housing (2) of the machine by means of a sleeve element (10) in the form of a hollow cylinder of rubber, the length of which is less than the length of the handle (7), characterized in that the sleeve element (10) with its inner surface is directly or indirectly connected to the shaft pin (0,5) and to its outer surface is directly or indirectly fixedly connected to the inner cylindrical surface of the handle (7) and has such an axial length that the torque point range in the sleeve element (10) within which, when applying forces (FS, Fd) to the handle, change from a compressive stress to a tensile stress lies between the machine housing (2) and the center of the handle and that the sleeve element has such a thickness and rigidity that the handle is allowed to pivot within an angle (° C) on either side of a central reference line (A) through the shaft pin (0,5) corresponding to the handle and static thrust (FS) applied to the machine and the dynamic vibration force (Fd) of the machine. Device according to claim 1, characterized in that the axial length of the sleeve element (10) is 20-H0 s of the length of the handle (7). Device according to claim 1 or 2, characterized in that the sleeve element (10) is with its cylindrical outer surface directly attached to the inner cylindrical surface of the handle and is directly attached to the surface of the shaft pin (H, 5) with its inner cylindrical surface. Device according to claim 1 or 2, characterized in that the cylindrical outer surface of the sleeve element (10) is connected to the inner surface of a first tube (11) of metal, which is fixedly mounted in the handle and that the inner part of the sleeve element (10) cylindrical surface is fixedly connected to the circumferential surface of a second tube (12), which is fixedly connected to the shaft pin (4,5).