DE1094546B - Coupling for the transmission of linear forces - Google Patents

Description

Coupling for the transmission of linear forces Often the task is Forces acting in a straight line either to transmit or not to transmit. the known arrangements contain for this purpose intermediate links that mechanically or operated electromagnetically. Such coupling devices work however, because of the often considerable moving masses, it is too slow for many purposes.

A device has already been proposed in which an elastic, magnetizable intermediate member, e.g. B. a sheet metal strip is provided, which when switched off. the device sags under the driving force and so this does not broadcast. However, if the intermediate link is switched on by means of a Electromagnet through this against a base made of non-magnetizable material pulled, it can no longer bend, but transmits the force.

Magnetic particle clutches work faster than these known devices for the transmission of axially directed forces; these consist of a magnetic powder filled cylinder in which there is a piston that is movable as long as the magnetic powder is not in the field of an electromagnet. As soon as the magnet is switched on, the viscosity of the filling increases so that the piston is practically non-positively connected to the cylinder. In another well-known The device is the variably controllable viscosity by the electromagnet A mixture of oil and iron filings are used to control the axial movements of the piston to dampen, so that vibration damping is achieved.

A difficulty with such devices is sealing the piston rod guide through the cylinder wall, because on the one hand it is easy to move should be, but on the other hand against the mostly composed of C51 and iron powder or the like The mixture must seal well.

This difficulty with couplings for transmission in a straight line more effective Forces is according to the present invention using a hollow body, its The viscosity of the filling can be changed by electromagnetic forces, thereby avoided that the hollow body is airtight by a membranarti, g deformable cover is closed, which in turn is connected to the driving part of the clutch is. The advantage of this coupling design is in particular that the volume of the hollow body remains constant and there is no need to seal moving parts.

Further features of the invention emerge from the subclaims in conjunction with the exemplary embodiment explained with reference to the listed drawings. In the drawings: Fig. 1 is the partially cut-open coupling cylinder, Fig. 2 is a section through the coupling device, Fig. 3 is a part of the device shown in section in Fig. 2 in the basic position, Fig. 4 is the part shown in Fig. 3 Device in working position, FIG. 5 shows an application example of the device with an electromagnet, a power source and cam contact. The hollow body 10, which is made of non-magnetizable material and preferably has a cylindrical shape, is formed by the cylinder wall 11 and the upper cover 12 . The lower end of the cylinder 10 is closed by an elastic membrane 14, which is at the edge. the cylinder wall is attached. The membrane 14 is made of a non-porous material which, for. B. rubber, leather or otherwise .an elastic material.

A drive rod 15 is attached in the middle of the membrane. Of the upper cover 12 and the membrane 14 are connected airtight to the cylinder wall, and also. the attachment of the drive rod 15 to the membrane is made airtight.

The inside of the cylinder 10 is filled with a mixture consisting of iron, nickel or steel powder and oil. The magnetizable powder can be used either alone or mixed with graphite powder. This mixture, which is liquid in itself, is resilient when a pressure is exerted on the membrane, and when the drive rod 15 moves upwards against the cylinder 10, the force exerted is transmitted by the liquid inside the cylinder to all inner surfaces of the cylinder and the surface of the membrane. whereby the membrane 14 assumes the shape shown in FIG. 2 and the force exerted is absorbed by the shift in position of the magnetizable mixture. If, however, at the time of the upward movement of the drive rod 15, the liquid mixture is exposed to a magnetic force field, the magnetizable particles of the mixture align with the lines of force of the magnetic field and resist a shift in position, so that the motive force exerted on the drive rod 15 rises above the mixture the upper cylinder cover 112 and the rod 13 connected to it is transmitted. A compression spring 16 arranged inside the cylinder is supported on the one hand against the cover 12 and on the other hand against the membrane 14 and moves the drive rod 15 back into the basic position shown in FIG. 3, as will be described later.

The cylinder 10 is surrounded by the pole pieces 18 and 19 of an Eelktromagne'ten 17 with the winding 22 (FIG. 5). The electromagnet 17 is fastened to a support plate 23 by means of screws 21 (FIGS. 2, 5). A cover plate 20 is adapted to the pole pieces 18 and 19 and fastened to them by means of the screws 24 and provided with an opening for the passage of the driven rod 13. Between the cylinder cover 12 and the cover plate 20 hzw. A spring 25 is arranged between the pole pieces 18 and 19 (FIGS. 2, 3, 4 and 5) which presses the cylinder downwards. The downward movement of the cylinder 10 between the pole pieces 18 and 19 under the action of the spring 25 is limited by a shoulder 26 formed on the inner sides of the lower ends of the pole pieces. A bearing 27 fastened to the support plate 23 by means of the screws 28 serves to guide the driven rod 13. A bearing 29 fastened to the support plate 23 by means of the screws 30 guides the drive rod 15. A motor 31 is attached to a lateral extension 32 of the support plate 23 , and on its shaft 33 are two cams 34 and 35. The cam 35 moves the drive rod 15 upwards against the cylinder 10 once with each revolution, and the cam 34 closes during it One revolution a contact formed from the contact elements 38 and 37. The excitation circuit for the electromagnet 17 is shown in FIG. 5 and contains the magnet winding 22, the contact 37, 38, the battery 45 and a switch 46.

The cams 34 and 35 are shaped so that the contact 37, 38 is already is closed before the drive rod 15 begins its upward movement, and remains closed until the drive rod has fully returned to its home position is. When the switch 46 is open, the drive rod 15 is activated by the jib 35 moved upwards against the cylinder 10 and down again by the spring 16. The pressure exerted during the upward movement of the drive rod 15 is determined by the Change in shape of the membrane, the change in position of the magnetizable mixture of the Cylinder and received by the spring 16, as shown in FIGS is. However, if the switch 46 is closed, then the electromagnet 17 generates a magnetic field; due to the orientation of the non-magnetizable particles of the mixture within the cylinder 10, the upward movement of the drive rod 15 transmitted force applied to the cylinder 10 and the driven rod 13, as shown in FIG. As soon as the cam 35 reaches the lower end of the Leaving the drive rod 15, the cylinder 10 and the rod 13 are actuated by the spring 25 returned to their normal position. To make the magnetic coupling shown, the magnetic field is preferably generated, when the cylinder 10 and the drive rod 15 are in their position shown in FIG Normal position. In this position there is little or no movement transferred to the driven rod 13. The cam 34 is shaped so that when closed Switch 46 of the cylinder 10 is exposed to the magnetic field only when the drive rod 15 is actuated by the cam 35. This ensures the return of the actuator stem 15 under the control of the spring 16 and 25 in their normal position (Fig. 3) during the time in which the cam 35 runs freely.

Claims (4)

PATENT CLAIMS: 1. Coupling for the transmission of rectilinear forces by means of a filled hollow body, the filling of which can be changed in viscosity by electromagnetic forces, characterized in that the hollow body (10) is hermetically sealed by a membrane-like deformable cover (14), which in turn with the driving part (15) of the coupling is connected. 2. Coupling according to claim 1, characterized in that a spring (16) is the membrane-like Cover (14) of the hollow body (10) in the switched-off state of the coupling against pushes the driving part (15) of the clutch. 3. Coupling according to claims 1 and 2, characterized in that a spring (25) the hollow body (10) when switched off Clutch pushes in the opposite direction to the driven part (13) of the clutch. 4. Coupling according to claims 1 to 3, characterized in that the hollow body (10) with the spring (25) in which, preferably from the pole pieces (18, 19) of an electromagnet (17) formed housing is movably guided. 5. Application of the coupling according to the Claims 1 to 4 in one consisting of cam disks and associated sensing elements Drive device, characterized in that the driving part (15) of the coupling is designed as a sensing element for a first cam disk (35) and during the Duration of the actuation of the driving part (15) by this \? Ockenscheibe (35) a second cam disk (34) has a contact (37, 38) for energizing the electromagnet (17) closes. Considered publications: German Patent Specifications No. 589 '132, 817 978: French patent specification No. 988 971; Die Technik, Vol. 5, No. 4, April 1950, pp.173 to 176.