CS268402B1 - A latch mechanism for converting a swinging motion into a discontinuous rotational motion - Google Patents

Abstract

The latch mechanism has two single-arm latches and one double-arm latch arranged on the swing lever, the bearing pins of which are arranged in the vertices of an equilateral triangle, through the geometric center of gravity of which the axis of swing of this lever passes. The bearing pins on which the latches are freely rotatable. They are kinematically connected to the member for controlling the direction of rotation of the ratchet, while these latches are connected to their bearing pins only by springs inserted transversely into their bearing pins. By rotating and locking the members in the appropriate position, each pair of latches, namely one of the single-arm latches and one of the arms of the double-arm latch, are elastically pressed into functional engagement with the ratchet. This allows the function of the latches and their springs to be changed with a single action.

Description

The present invention relates to a latch mechanism for converting an oscillating motion into an intermittent rotational motion.

Solutions are known in the art which, using a single ratchet engaging ratchet, convert only one oscillation of each oscillating lever swing into a rotary ratchet movement, and using two latches can also use the ratchet's reverse swing to move the ratchet another pivot step in the same direction. . However, if the direction of rotation of the ratchet is to be changed more often, then there are problems with these solutions. It is necessary to engage another pair of oppositely oriented latches in the operation of the mechanism and use ratchets with oppositely oriented saw teeth, or to rebuild the whole mechanism, ie turn it, while it is necessary to change the direction of spring, which press these latches into engagement with the ratchet.

The object of the invention is to eliminate these drawbacks and to elaborate such a latching mechanism using a lever carrying these latches to rotate the ratchet in both directions of swing so that by simple intervention this mechanism can only be adjusted for the desired direction of rotation of the latch-driven ratchet.

Tofio is achieved in that the latch bearing pins of such a mechanism are rotatable and are kinematically connected to a member for controlling the direction of action of these latches on the ratchet and thus for controlling the direction of its rotation, a spring having a free the end is connected to the respective latch. The desired effect is achieved by arranging three latches on the double-reversible pivot lever of this mechanism, namely two single-arm and one double-arm, symmetrically placed between the two single-arm latches, the bearing pins of which are arranged at the vertices of an equilateral triangle whose geometric center of gravity is of this double reversible lever. In addition, even when the bearing pins are rotatable, all three latches on these bearing pins are rotatable. In accordance with the invention, the member for controlling the direction of rotation of the ratchet, which is kinematically connected to the latch bearing pins, is a disk with radial notches with which radial pins are engaged with the latch bearing pins, or a spur gear engaging gear pinions arranged fixedly on the bearing pins. latch pins. In both of these alternative embodiments, the effective radius of engagement in the kinematic connection between the bearing pins and the ratchet direction control member on the side of this member is larger than the radius on the bearing pin side.

This solution has several advantages and benefits. This is because it does not limit the mechanism in its ability to drive the ratchet in the same direction in both swings of the rocker arm - in one direction or the other - but provides the ability to easily readjust for one or another sense of rotation of the ratchet without having to adjust or they had to move the springs so that they always pushed the latches towards the ratchet. This is made possible by the fact that the latch bearing pins are rotatable and the springs are embedded transversely therein, so that by rotating these bearing pins, which are kinematically connected to the ratchet rotation control member, the springs spring in the sense in which for example, for a changed sense of action of the latches.

These advantages will be elucidated on the basis of the description of an exemplary embodiment of the mechanism according to the invention shown in the drawings, in which Fig. 1 is an overall view of a mechanism for converting a rocking motion into a continuous rotary motion, with one embodiment of ratchet direction control means. and Fig. 2 is another embodiment of this device.

The oscillating movement of the lever 7 (Fig. 1) is converted into a continuous rotational movement of the ratchet 2 by a system of latches 3, 4, 5 arranged symmetrically about the axis 6 of this oscillating lever K. The system comprises two latches 3, 4 one-arm and one two-arm latch 5. stored symmetrically between them. The bearing pins 7, 1, 9 of these latches 3, 4, 5 are rotatably mounted in the housing 1a and are kinematically connected to each other with a member 10 for controlling the direction of rotation of the ratchet 2, being transversely embedded in each of these bearing pins 7, 8, 9. spring that

CS 268402 B1 is connected by a second free end and a respective latch. In the bearing pin 7 of the first single-arm latch 6 it is a spring 11, in the bearing pin 8 of the second single-arm latch 4 it is a spring 12 and finally in the bearing pin 9 of the third two-arm latch 5 it is a spring 13. The purpose of these springs 11, 12, 13 is to press the respective latches 6, 4, 6 engage with the teeth of the ratchet 2, so that the oscillating movement of the lever 6 always results in one-way engagement of these latches 3, 4, 6 with the ratchet 2. Due to the two-arm latch 5, essentially two pairs of latches are available - each of them for One sense of rotation of the ratchet - so if One pair is engaged with this ratchet 2, the other pair must be out of engagement with it. Due to the given condition that the two oscillations of the lever 1 be used for the same direction of rotation by the ratchet, the bearing pins 7, 8, 9 are arranged in the housing 1a of the lever 6 so that the projections of their axes define the vertices of an equilateral triangle 14 whose geometric center of gravity 15 is in axis 6, around which the lever £ swings. This embodiment also ensures that the angular rotation of the ratchet 3 remains the same in both directions of the swing of the lever £.

The kinematic connection of all three bearing pins 7, 8, 9 with the member 10 for controlling the direction of rotation of the ratchet 2 and the transverse interlocking of the springs 11, 12, 13 in them is monitored simple adjustment of the mechanism, ie change of latch pair activity and sense of the action of springs, 11, 12, 13. This kinematic connection can certainly be solved in principle by several transmission mechanisms, for the choice of which, however, the decisive factor is the operating and production conditions to which it must comply. However, the construction of the latch mechanism itself also plays a role here, namely the fact whether the arms 5a and 5b of the two-arm latch 6 participate in the rotation of the ratchet 2 as push or pull arms. Although a simpler solution of the latching mechanism using the two arms 5a, 5b as push arms is shown in the drawing as an example, it is also possible to use a solution with these pull arms. This alternative requires only a different design of the ends of the arms 5a, 5b for the two-arm latch 5, but a more complicated connection of the bearing pin -9fs by the member 10. It is therefore more advantageous to solve this kinematic connection, e.g. radial pins embedded in the bearing pins 7, 8, 9 of the latches 3, 4, 5 (Fig. 2). Thus, in this second embodiment, the control member 10 is represented by a disc with radial notches 16, with which the radial pins 17 are in engagement firmly connected to the bearing pins 7, 8, 9 of the latches 3, 4, 5. It is quite natural that the shape of the notches 16 corresponds to the conditions of the rolling of the flanks of the pins 17, the angular rotation of the bearing pins 7, 8, 6 corresponding only to the need to resiliently press the catches 3, 4, 5 against the ratchet teeth 2 of said first embodiment. between. No. 7, 9, 9 and the member 10, this member is designed as a spur gear 18 (Fig. 1), which is in permanent engagement with the pinion 19, 20, 21, firmly connected with these bearing pins. In both of these embodiments, the latches 3, 4, 6 on the bearing pins 7, 8, 9 are freely rotatable and are connected to them only by said springs 11, 2, 13, embedded transversely into these bearing pins. Thus, when the bearing pins 7, 8, 9 are rotated, the springs 11, 12, 13 are means for bringing the respective latches into engagement with the ratchet 2 and further angular rotation of the member 10 is resiliently pressed against the ratchet 2, as this further rotation of the spring member 10 , 12, 13 strings. For this purpose, the pin with the axis 6 around which the lever £ oscillates can be provided with a square for the tubular key so that the member 10 can be easily rotated to a suitable position. A second such opening 25 in the housing 1a serves to lock the member 10 in its second active position for the opposite direction of rotation of the ratchet 2 and the third opening 26 serves to secure the neutral position of the latches 3, 4, 5 in which they are out of engagement with the ratchet 2. In order to achieve the pressure of the latches 3, 4, 5 by its springs 11, 12, £ 3, the effective radius R of mutual engagement in the kinematic connection between the bearing pins 7, 8, 9 and the member 10 on the side of this member is greater than the radius. bearing pins.

Since the ratchet 2 can rotate in both directions, its teeth 2a (Fig. 1) are square in shape with the sides parallel, so that the closure of all the latches 6, 4, 6 is always the same, so that the ratchet 2 is to rotate in one direction or another.

CS 268402 Bl

When the reversing lever 1 swings, for example, downwards, i. in the sense of the arrow 22, in the position of the member 10 shown in FIG. 'takes a stroke so that, in the subsequent swing of the lever 6 in the sense of the arrow 23, it engages with its tooth on the top of the ratchet 2, which leaves the latch 3 during this swing. they both shoot it in the same direction and at the same angle. By reversing the movement of the ratchet 2 by rotating the member 10 in the opposite direction and securing it with the locking pin 24 in the hole 25, the latch g is deflected away from the ratchet 2 while the latch 4 with its tooth on the top tilts together with the arm 5b. In this case, the springs 12 and 13 are tensioned in the opposite direction than before, and the latches are resiliently pressed against the ratchet 2. Then, when alternating the swing of the lever 6 in the sense of the arrows 22, 23, the latch 4 and the arm 5b of the two-arm latch 6 engage from the opposite side of the ratchet 2 and thus rotate it in the opposite direction than before.

The described mechanism finds its application wherever it is a matter of converting a rocking motion into a rotary motion, and its construction proves to be advantageous wherever it is necessary to reverse this rotational motion. One of the fields of application of this mechanism is, for example, construction, where by connecting a ratchet to a nut it would be possible to create an effective jack usable in a system of such devices applied in the method of raised ceilings.

In order to prevent the ratchet from carrying back when the stroke is picked up by the latches, there is in fact no need for a locking latch, because the other active latch actuates immediately after the end of the stroke of one active latch. In case, for example, when using the described mechanism in the construction of screw jacks for the method of raised ceilings, it would be necessary to block the reverse rotation of the screws due to the release of their elastic torsion, it is possible to use a locking latch known per se.

Claims (6)

. OBJECT OF THE INVENTION A latch mechanism for converting an oscillating movement into an intermittent rotational movement, consisting of a ratchet and latches resiliently pressable relative thereto, arranged for two-reversible pivoting work. the axis YykyYiL is already symmetrical to the bearing pins of these latches, characterized in that the bearing pins (7, 8, 9) of these latches (3, 4, 5) are rotatable and are kinematically connected to the member (10) for controlling the direction of action of these latches (3, 4, 5) on the ratchet (2), a spring (11, 12, 13) being transversely embedded in each of the bearing pins (7, 8, 9), the free end of which is connected to the respective latch (3, 4, 5). 2. Latch mechanism according to claim 1, characterized in that three latches (3, 4, 5), namely two single-arm latches (3, 4) and one two-arm latch (5), symmetrically mounted, are arranged on its two-reversible pivot lever (1). between the two single-arm latches (3, 4), the bearing pins (7, 8, 9) of which are arranged at the vertices of an equilateral triangle (14), the geometric center of gravity (15) of which is in the axis (6) of oscillation of this double-return lever (1). 3. Latch mechanism according to items 1 and 2, characterized in that the latches (3, 4, 5) are rotatable on their bearing pins (7, 8, 9). 4. Latch mechanism according to items 1 to 3, characterized in that the member (10) for controlling the direction of rotation of the ratchet (2), kinematically connected to the bearing pins (7, 8, 9) of the latches (3, 4, 5), is a disc with radial notches (16) with which the radial pins (17) engage with the bearing pins (7, 8, 9) of the latches (3, 4, 5) are engaged. 5. A latch mechanism according to items 1 to 3, characterized in that the member (10) for controlling the direction of rotation of the ratchet (2) is a spur gear (18) engaging the toothed gears. CS 268402 Bl torks (19, 20, 21) arranged on the bearing pins (7, 8, 9) of the latches (3, 4, 5). 6. Latch mechanism according to items 1 to 5, characterized in that the effective radius (R) of mutual engagement in the kinematic connection between the bearing pins (7, 8, 9) and the member (10) for controlling the direction of rotation of the ratchet (2) is on this side. member (10) larger than the radius (r) on the side of the bearing pins (7, 8, .9).