NL9300268A - Adjustable sprocket wheel - Google Patents

Abstract

A toothed wheel, which is intended to interact with an endless transmission member with transmission elements, for example a chain with links or a toothed belt, which toothed wheel bears a number of projections arranged on the circumference, which projections are each provided with a contact surface for interacting with the transmission members, the pitch of which contact surfaces corresponds to the pitch of the transmission members. The toothed wheel is provided with adjustment means for adjusting the pitch of the contact surfaces.

Description

Adjustable chain wheel

The invention relates to a sprocket, intended to cooperate with an endless transmission member with transmission elements, for example a chain with links or a toothed belt, which sprocket carries a number of circumferentially arranged projections, each projection having a contact surface for cooperation with the transmission members, the pitch of which contact surfaces corresponds to the pitch of the transmission members.

Such a sprocket is very common and is used, for example, in connection with an endless chain that can transfer forces from and / or to the sprocket.

As a result of use, the chain can show wear, whereby an effective elongation occurs, because the contact surfaces over which the links hinge together with each other start to show wear. This increases the pitch between the links of the chain, so that it no longer corresponds to the pitch of the contact surfaces. As a result, it cannot be avoided that the forces to be transmitted are no longer distributed homogeneously over the links of the chain and the contact surfaces of the sprocket, which results in accelerated wear, necessitating early replacement.

To overcome this great drawback, the invention proposes a gear wheel which is provided with adjusting means for adjusting the pitch of the contact surfaces.

In a particular embodiment, the gear wheel can have the special feature that the adjusting means can be pre-adjusted to a selected position. For example, use can be made of screwing means which individually or jointly bring the contact surfaces into a new position, in which the pitch of the contact surfaces is equal to that of the links of the chain.

Preferred, however, is an embodiment in which the adjusting means are self-adjusting.

This variant can have the special feature that the adjusting means comprise spring means.

In an embodiment in which each projection is radially displaceable, the spring means can be arranged to push the contact surfaces outward.

In an embodiment in which each projection is tangentially displaceable, the spring means can be arranged for resetting the contact surfaces in a central resting position.

It is noted that in an embodiment in which the protrusions are radially displaceable, the mutual angular positions of the contact surfaces remain the same. This is also the case with the embodiment in which the adjusting means can be pre-adjusted to a selected position. As a result, the resulting play in a chain can be effectively compensated.

However, in an embodiment in which the protrusions are tangentially displaceable, the tangential displacement can act only over the operative part of the sprocket, i.e. that part, in which the contact surfaces co-operate with the links of the chain.

There can be no question of effective extension compensation here. Such an embodiment can therefore also be combined, for example, with a known chain tensioner, whereby the chain is for instance pressed out of its nominal path by a free-rotating roller.

In a preferred embodiment, the gear wheel has the special feature that each protrusion is pivotable in the main plane of the gear wheel. This swingability means two coupled degrees of freedom of movement, namely a radial degree of freedom and a tangential degree of freedom.

A preferred embodiment, which is completely self-adjusting, is characterized in that each protrusion has two contact surfaces, which are arranged such that they can interact simultaneously with two contact surfaces at both ends of a transmission element and each protrusion is slidably guided by two of the gear and the projections forming part of the projections, cooperating guide pins and slotted holes, which slotted holes have such a shape that the projection can undergo an angular rotation, wherein in one extreme angular position the projection is pivotable around one pin and in the other extreme angular position the projection is pivotable around the other pen.

In order to ensure that the protrusions are in the appropriate position prior to engagement with the transmission elements, use can be made advantageously of resetting spring means which push the contact surfaces to an extreme position, in which the pitch of the contact surfaces is maximized is. It should be noted that the dimensioning of the gear must be such that the contact surfaces can indeed come into contact with these elements at the start of engagement with the transmission elements.

The use of reset spring means can be dispensed with under certain circumstances, for example in the case where, in the free, i.e. unloaded, condition of the projections, they are located on the underside of a vertically arranged gear wheel. However, it must then be ensured that gravity is then sufficient to tilt the protrusions to the desired position, overcoming the associated frictional forces.

The invention will now be elucidated with reference to the annexed drawing. In the drawing: figure 1 shows a schematic view of a gear wheel according to the invention in a first embodiment; figure 2 shows a view corresponding with figure 1 of a second embodiment; figure 3 shows a schematic view of a gear wheel in a third embodiment; figure 4 shows a schematic view, in which manner the force interaction between the sprocket and the chain according to figure 7 takes place; figure 5 shows a fourth exemplary embodiment in partly broken away perspective view; figure 6 shows the cross section V-V according to figure 4; and Figure 7 is a side view of a fifth preferred embodiment.

Figure 1 shows a gear 1 with radially slidable projections 2, which are pushed radially outward by helical springs 3. Each projection 2 has a hollow contact surface 4 for cooperation with the hinge shafts 5 of a chain 6. The hinge shafts form the coupling between the links 7 of the chain 6. In the case in which the pitch of the hinge shafts 5 has increased due to aging and wear, the gear 1 is nevertheless able to engage with the contact surfaces 4 exactly on the respective contact surfaces of the shafts 5. The protrusions 2 move under the influence of the springs 5 over the active part of the gear 1 shown in the drawing to the left. outside, increasing the effective pitch circle relative to the situation where the chain 5 is not yet worn. It will be clear that in the rest position, that is to say in the non-active right-hand part of the gear 1, the protrusions 2 are urged towards a largest plug-in circle. By engagement with the chain 6, stabilization takes place on the correct plug-in circle.

Figure 2 shows a gear wheel 8, in which protrusions 9 are pivotable around pivot shafts 10 in the main plane of the gear wheel 8. Each protrusion 9 has two compression springs, 11, 12 respectively, which push the respective protrusion to a central resting position. In the condition in which the chain 6 is stretched by wear, the positions of the contact surfaces 4 adjust so that in the effective part of the sprocket an angular rotation of the projections occurs, whereby adaptation to the pitch of the pivot shafts 5 takes place automatically .

Figure 3 shows another embodiment. The gear 13 according to figure 3 carries a number of protrusions 14 which are pivotable around pivot shafts 15. These protrusions each carry two hollow contact surfaces, which are indicated with 16 and 17 respectively. An adjustable stop in the form of an adjustment bolt 18 is added to each projection 14 and limits the inward stroke of the respective projection. In this way, on the basis of the effective pitch of the corresponding hinge axes 19, the adjustment of each bolt can take place such that the contact surfaces 16 have the same mutual pitch as the hinge axes 19. The direction of rotation is indicated by an arrow 40.

As Figure 3 clearly shows, the pivot shafts 19 cooperate with the front contact surfaces 16, while the pivot shafts 20 cooperate with the rear contact surfaces 17. As is further apparent from Figure 3, the contact surfaces 16, 17 each have such a shape that the positions of the pivot shafts 19, 20 relative to the contact surfaces 16, 17 co-operating therewith are not fixed, but allow a certain play.

Figure 4 shows how the variant according to Figure 3 can be modified by means of spring means (not shown) in order to obtain a self-adjusting gear. The gear wheel 21 has roughly the same structure as the gear wheel 13 according to Figure 3. Corresponding elements are here also designated with the same reference numerals as in Figure 3. The gear 21 is driven by a torque M and thus drives the chain 6 by means of the contact surfaces 16. The projections 14 are pushed out by means of spring means (not shown). In the leftmost position in figure 3a, in which a link has come into contact with a projection 14, the preceding link is already hinged relative to the relevant link. The tension in the chain can, of course, only intersect the line between the center lines of the pivot shafts 19, 20. If the forces in question are decomposed, they must extend through the hinge shafts 15 for a mechanically stable situation. This self-adjusting action is obtained automatically in that a resultant force which does not extend through a pivot shaft 15 immediately results in a corresponding displacement of the respective projection 14, whereby the stable situation is obtained. Only when this condition of mechanical stability is met does a projection at rest.

Figures 5 and 6 show a gear 22, which comprises two flanges 23, 24, between which symmetrical protrusions 25 are slidably guided. The protrusions 26 each have a front hollow contact surface 26 and a rear hollow contact surface 27. Each protrusion has two slotted holes, a front slotted hole 28 and a rear slotted hole 29, respectively. With the slotted holes, guide pins 30, 31, respectively, interact with the flanges 23, 24 are connected. A reset spring 32 urges each projection 25 into the operative position shown on the left, in which the projection 25 is pivotable around the guide pin 31. Herein a force exchange with a respective link of a chain (not shown) can be effected by means of the contact surface 26. transferred. It is essential, as in the embodiment according to figure 4, that this embodiment is self-adjusting due to the pivotability around the pin 31.

Figure 7 shows a gear wheel 33 carrying slidably guided projections 34, each having two slotted holes 35, 36, which cooperate with guide pins 37, 38, respectively. The slotted holes 35 and 36 are arranged concentrically with the pins 38 and 37, respectively. As the figure shows, a first engagement of a link takes place by co-operation of the front contact surface 26 of a projection 34 with the pivot axis 19. The leftmost projection 34 in figure 6 shows this condition. Hinging takes place around the rear hinge pin 38. In the top position in Figure 6, the protrusion 34 with the ends of the slotted holes 35, 36 rests against the guide pins 37, 38. Then, a hinge takes place around the front guide pin 37. Return springs 39 penetrate the protrusions 34 to their extreme position, in which the position of the contact surfaces 26, 27 corresponds to the maximum pitch.

As figure 7 shows, in this extreme position contact with the shafts 19, 20 can certainly occur.

It should be noted that the use of the return springs 39 could in principle be waived in the case where the sprocket 33 is arranged vertically, the chain extends over the upper part thereof and gravity is sufficient about the projections 34 in the quadrant bottom left to the position indicated there. If desired, use could also be made of cam means, not shown, which in the said quadrant push the protrusions 34 to the desired starting position.

After the explanation given above with reference to Fig. 4, it will be clear that the gear 33 is a self-adjusting gear, which is self-adjusting and inherently stable.

Not shown is an embodiment in which a gear with fixed contact surfaces according to the teachings of the invention is adapted to the pitch of a stretched chain by effectively displacing the contact surfaces radially, for example by placing inserts thereon. Such an embodiment has a certain analogy with the sprocket according to figure 1, which however has the advantage of being able to adapt itself to the changed pitch of a chain.

Claims (10)

1. Sprocket designed to cooperate with an endless transmission member having transmission elements, for example a chain with links or a toothed belt, said sprocket carrying a number of circumferentially arranged projections, said projections each having a contact surface for cooperation with the transmission members, the pitch of which contact surfaces corresponds to the pitch of the transmission members characterized by adjusting means for adjusting the pitch of the contact surfaces. Gear wheel according to claim 1, characterized in that the adjusting means can be pre-adjusted to a selected position. Gear wheel according to claim 1, characterized in that the adjusting means are self-adjusting. Gear wheel according to claim 3, characterized in that the adjusting means comprise spring means. Gear wheel according to claim 1, characterized in that each projection is movable radially. Gear wheel according to claim 1, characterized in that each projection is movable tangentially. Gear according to claim 1, characterized in that each protrusion is pivotable in the main plane of the gear. Sprocket according to claim 7, characterized in that each projection is pivotable around a hinge axis. Gear according to claim 7, characterized in that each projection has two contact surfaces, which are arranged such that they can co-act simultaneously with two contact surfaces at both ends of a transmission element and each projection is slidably guided by two of the gear and the projections forming part of co-operating guide pins and slotted holes, which slotted holes have such a shape that the protrusion can undergo an angular rotation, wherein in one extreme angular position the protrusion is pivotable around one pin and in the other extreme angular position the protrusion is pivotable around the other pen. Gear according to claim 9, characterized by resetting spring means which push the contact surfaces to an extreme position in which the pitch of the contact surfaces is maximum.