DE228008C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- JVr 228008 - CLASS 21 /. GROUP

Patented in the German Empire on September 30, 1908.

The previously common elevator winches with locking mechanisms are in their arrangement very complicated, and their individual parts require if the winch meets the conditions imposed on them should suffice, an exact processing.

An elevator winch with a locking mechanism that stands out for the simplicity of its individual parts and through their clear assembly of the previously common devices advantageously distinguishes, forms the subject of the invention.

The new winch consists essentially of one on the rope drum or the rope sheave eccentrically arranged, so influenced by the hand crank clamping member that when Winding up or down the load, the clamping member on the inner smooth wall of the drum or disc enclosing housing slides, however, when the crank is released ■ is instantly supported against the housing wall, which prevents the load from falling.

On the drawings are in Figs

two embodiments of the subject matter of the invention shown in application to arc lamp winches. 1 shows one embodiment in a longitudinal section along the line AB in FIG. 2 and FIG. 2 shows a cross section along the line CD in FIG. 1. FIGS. 3 and 4 show a further embodiment in longitudinal and cross-section shown after the lines EF and GH .

FIGS. 5 to 10 show schematically the differences between the known an-order, in which a clamping piece with both end points lying on a chord is pressed against the inner housing wall, and of the new arrangement, FIGS. 5 to 7 referring to the known arrangement, FIG. 8 to 10 relate to the subject matter of the invention.

In the embodiment according to FIGS. 1 and 2, the cable drum α is supported on the one hand by the elongated hollow hub b in the front c of the winch housing, and on the other hand by the axis d fastened in the drum α in the rear e of the winch housing. The axis d is expediently extended to the front edge of the hollow hub b . On the front surface of the cable drum α is now, rotatable about the pin f (Fig. 2), the clamping piece g eccentrically articulated, whose sliding or clamping surface h slides on the inner wall of the front housing part c. The clamping piece g has a thumb i, which is directed towards the axis d and which protrudes with clearance through a correspondingly shaped recess in the hollow hub b. The hollow hub has a shoulder k on its inner surface. The nose m arranged on the crank I can move between this approach k and the thumb i of the clamping piece g . A spring η attached to the hollow hub b rests on the thumb i of the clamping piece g and presses its sliding surface h against the inner housing wall. ... ■■; ■ * ,;>:;

The mode of operation of this arrangement is the following:

When the load is wound up in the direction of the clockwise movement, the nose m of the hand crank I presses against the shoulder k of the hollow hub b and takes the cable drum α directly with it (FIG. 2). The surface h of the clamping piece g is here under spring pressure

(2nd edition, issued on November 35th igioj

guided along the inner housing wall, because the pin f of the clamping piece g also moves in the clockwise direction and drags the clamping piece g .
If during this lifting movement suddenly the pressure on the crank / stops, so the crank thumb m is no longer in contact with the lugs k , the pull of the load to be lifted will endeavor to move the cable drum α and thus also the clamping piece g in the to rotate in the opposite direction to the lifting movement. At this moment, a strong clamping effect will occur between the sliding surface h and the inner housing wall, which is increased by the additional pressure of the spring η , ie it is impossible to continue turning the winch.

When lowering the load, the clamping effect between the sliding surface h and the housing wall is canceled by the fact that when the hand crank I is turned in the direction opposite to the clockwise movement, the nose m of the hand crank presses against the thumb i of the clamping piece g. As can be seen, the effect of the spring η and the clamping pressure of the sliding surface h against the housing wall are thereby canceled, so that the vented clamping piece g can slide along the housing wall without friction. If the pressure on the hand crank I ceases during this movement, the same clamping effect occurs between the sliding surface k and the housing wall as previously described for the lifting movement.

In the second embodiment according to FIGS. 3 and 4, the same parts corresponding to FIGS. 1 and 2 have been given the same designation for the sake of clarity. In this embodiment, a clamping piece g, which is mounted eccentrically on the cable drum α and has a sliding surface h , also grinds on the inner housing wall. This arrangement differs from that shown in FIGS. 1 and 2 in that the hollow hub according to FIGS. 1 and 2 is designed here as a loose intermediate member ζ which is rotatably mounted on the axis d, on the one hand in the front wall of the winch housing, on the other hand in the cable drum α itself receives leadership. A narrow cutout at right angles to the axis is provided on the intermediate member ζ to accommodate the clamping piece g equipped with the two stop surfaces 0, p and the crank thumb m.

The intermediate piece ζ is pressed against the clamping piece g by a spring n, one end of which is in the intermediate piece z and the other is mounted on the cable drum.

The mode of operation of this arrangement is as follows:

When the load is wound up in the clockwise direction, the pressure of the crank thumb m against the stop surface 0 (Fig. 4) of the clamping piece g overcomes the cable and the clamping piece g is lifted against the action of the spring η . The cable drum can therefore follow the crank movement, the surface h sliding on the housing wall. If the pressure on the hand crank I ceases, as a result of the cable pull - in the direction of the arrow - the cable drum will immediately come to a standstill, because the intermediate link ζ is pressed against the thumb i by the pull of the spring η and the area h of the clamping piece is thereby expanded g against the housing wall.

When lowering the load counterclockwise, the crank thumb m is pressed against the stop surface p of the clamping piece g and the clamping effect of the sliding surfaces is canceled. The load to be lowered can therefore follow the movement of the crank.

If during this movement the pressure on the hand crank / suddenly stops, e.g. B. by accidentally letting go of the crank, so also occurs with this arrangement instantaneous clamping, because the intermediate piece ζ exerts pressure on the thumb i through the intermediary of the spring η and the bearing friction in the housing, whereby the sliding surface of the clamping piece g is against the Inner wall of the housing supports.

The difference between the described elevator winches and the known devices becomes clear when comparing FIGS. 5 and 8. If one imagines that the rod hf in FIG. 8 is added to the chord beyond f (point t) in order to produce an external similarity to the rod ht in FIG. 5, the pressure of the load Q only acts on the braking track in the direction th , while according to Fig. 5, the pressure of the load Q acts perpendicular to the tendon ht.

If these relationships are transferred to the wedge (Figs. 6 and 9), the difference between the two explanations becomes even clearer. In the embodiment according to FIG. 6, the load acts on the head of the wedge. The wedge at angle α is therefore immediately clamped by the load Q. According to FIG. 9, on the other hand, the load Q acts almost in the opposite direction, it acts at right angles to the wedge surface uv and thus tends to push out the wedge. The distance uv corresponds to the distance uv in FIG. 8.

If these differences are again transferred to the winches themselves, FIGS. 7 and 10 result. FIG. 7 relates to the known form, FIG. 10 to the new one. Fig. 7 shows the tendon as a section from the wedge, which is fixed in the wedge joint as a result of the pressure of the load Q acting on it at right angles.

is jammed. The wedge is released by the pressure q , which is also perpendicular to the tendon and counteracts the load Q. Fig. 10, on the other hand, shows the force effect in the new shape, it represents a knee lock at angle α, the pressure of which at point N can easily be calculated according to the instructions in the figure. The load acts in the direction of the clamping piece fh, which tries to free itself depending on the size of the component s.

The intended loosening of the clamping piece of the winch takes place by a slight pressure q exerted on the clamping piece, which overcomes the friction.

With regard to the mode of operation, a particular advantage of the new arrangement is to be seen in that the locking member is lifted off the braking track by a low pressure.
Furthermore, the embodiments according to FIGS. 1 to 4 have the significant advantage that moving the cable drum, thus raising and lowering the load, is not possible without a special crank suitable for the device.

Instead of the cable drum α shown in the drawing, cable sheaves can easily be used.

Claims (5)

Patent Claims: i. Elevator winch with automatic locking mechanism, especially for arc lamps, characterized by an eccentrically and articulated on the one hand on the cable drum, on the other hand against the Wall of the winch housing supporting clamping piece, such that the load pressure acting in the direction of the clamping piece to mostly causes the frictional pressure, to a lesser extent this is expediently under Seeks to loosen the clamping piece standing under spring pressure, whereby an automatic lowering of the Load is prevented, while the clamping piece is lifted during the intended lowering by the crank moved backwards will. 2. embodiment of the winch according to claim i, characterized in that the eccentrically mounted clamping piece (g) is equipped with a thumb facing the axis of rotation (d) of the winch [i in Fig. 2), which is secured by a recess on the cable drum ( a) or the hollow hub (b) fixedly arranged on the pulley protrudes, and when the load is lowered, influenced by the crank thumb (m) , causes the clamping piece (g) to be released against the spring pressure. 3. Embodiment of the winch according to claims 1 and 2, characterized by a spring (n in Fig. 2) which acts directly on the eccentrically mounted clamping piece (g ) and which is attached to the hollow hub (b) connected to the cable drum or pulley. 4. Embodiment of the winch according to claim i, characterized in that the spring attached to the cable drum or pulley on the one hand acts on the thumb (i in Fig. 4) of the eccentrically mounted clamping piece with the mediation of an intermediate member rotatable on the axis of the winch (z) , the other end of the spring being attached to this link. 5. embodiment of the winch according to claims 1 and 4, characterized by the mounting of the intermediate member, which is under spring pressure and rotatable on the winch axis in the front wall of the winch housing, which as a result of the pull the load to be lifted or lowered causes a bearing friction of the intermediate member in the housing wall, which supports the effect of the spring on the clamping piece. 1 sheet of drawings.