Silent Sprocket/Gear For Transmission Chains, In Particular For Motorcycles, And Mold Components For Its Production

Abstract

The problem of progressive deforming of the silencing rubber by the motion transmission member (chain) is present in silenced sprockets. In particular for a toothed crown, lacking a central hub, the problem of the deforming or lowering of the rubber hasn't been resolved adequately. In the case of a pinion with a hub, an excessive quantity of rubber is used. The silenced sprocket of the present invention comprises, adjacent to the base of its teeth (105), a circular channel, or bilateral channel (200), on the metal body of the sprocket itself. On the inner circular step (110) of the channel (200) are discharged the forces created in the rubber by the transmission chain. The bilateral channel has a minimal radial extension, such as about cm in the motorcycle field. In general the silencing rubber element (106) and the bilateral channel (200), which creates its housing, have a minimal radial extension compared to the sprocket radius. The invention also comprises a molding technique that uses special molding components (107a, 107b), adapted to apply the rubber silencing element on the sprocket metal body. These components are of annular circular shape, U cross section and a width essentially corresponding to the channel (200) width, rendering the mold independent from the specific shape of the sprocket metal

Claims

1. Silent sprocket/gear of the toothed crown type without a hub, comprising a circular disc-shaped metal body having a plurality of peripheral teeth and a center with a possible central hole, further comprising an elastic silencing member applied by means of injection molding on the metal body of the silent sprocket/gear, said elastic silencing member having the following characteristics: it is extended on each side of the metal body, in an area arranged all around the center, starting from a substantially circular ideal line and directly adjacent to the base of said peripheral teeth; it passes through a plurality of through openings obtained in the metal body and arranged in said area; it projects laterally with respect to the metal body, forming, on each side of the silent sprocket/gear, respective peripheral outer circular cylindrical surfaces facing a radial direction, which surfaces are adapted to come in contact with a transmission chain; characterized in that in the metal body, in each of said areas of each side, the surface of the respective area forms a depression with respect to an immediately adjacent surface of the metal body, so as to create at least one inner step for support and contrast of the pressures that can be exerted by the chain and transmitted to the elastic silencing member through its peripheral outer circular cylindrical surfaces.

2. The silent sprocket/gear according to claim 1, wherein the said area forms, on each side of the metal body, a circular channel with constant cross-section, which is extended all around said center of the metal body.

3. The silent sprocket/gear according to claim 1, wherein the said through openings are equidistant through holes distributed in a concentric manner with respect to the center of the sprocket/gear.

4. The silent sprocket/gear according to claim 2, wherein the profile of the section of the circular channel is rectangular.

5. The silent sprocket/gear according to claim 2, wherein the profile of the section of the circular channel is wedge-like or dovetail-like.

6. The silent sprocket/gear according to claim 1, wherein the elastic silencing member is radially extended inwardly i.e. towards the center and the possible central hole of the metal body, starting from a distance of about 1 mm measured from the base of the teeth.

7. The silent sprocket/gear according to claim 1, wherein the material of the silencing member is nitrile rubber NBR.

8. The silent sprocket/gear according to claim 1, wherein that said area or said channel with constant section is extended width-wise for a minimum distance, corresponding for example to about cm, when the size of the primitive radius of the sprocket/gear is about 10 cm, and in any case it has a width of at least one order of magnitude smaller than the primitive radius of the sprocket/gear i.e. of the radius measured from the centre to the circumference of the primitive circle of the toothed crown sprocket/gear without a hub.

9. The silent sprocket/gear according to claim 2, wherein that said through holes occupy a width-wise distance, i.e. in a radial direction, inside the circular channel, which corresponds almost to the entire width of the circular channel itself.

10. The silent sprocket/gear according to claim 1, wherein said elastic silencing member forms a thin strip on each side of the sprocket/gear, having a width of for example about cm and a depth/projection>1 mm.

11. The silent sprocket/gear according to claim 1, comprising undercut openings.

12. The silent sprocket/gear according to claim 1, wherein that said elastic silencing member forms a single rubber body, with rubber pins that pass through the through holes.

13. The silent sprocket/gear constituting a pinion with a central hub, comprising a circular disc-shaped metal body bearing a plurality of peripheral teeth and a centre, 20 with a possible central hole in the hub, further comprising an elastic silencing member applied by means of injection molding on the metal body of the silent sprocket/gear, said elastic silencing member having the following characteristics: it is extended on each side of the metal body, in an area arranged all around the centre, 25 starting from a substantially circular ideal line directly adjacent to the base of said peripheral teeth; it passes through a plurality of through openings obtained in the metal body and arranged in said area; it projects laterally with respect to the metal body, forming on each side of the silent sprocket/gear respective peripheral outer circular cylindrical surfaces facing a radial direction, which surfaces are adapted to come in contact with a transmission chain; characterized in that in the metal body, in each of said areas of each side, the surface of the respective area forms a depression with respect to an immediately adjacent surface of the metal body, so as to create at least one inner step for support and contrast of the pressures that can be exerted by the chain and transmitted to the elastic silencing member through its peripheral outer circular cylindrical surfaces, and that said inner step is arranged at a set distance from the hub in such a manner that a substantially planar annular surface is present between said inner step and the hub of the sprocket/gear or pinion, on each side.

14. The silent sprocket/gear according to claim 13, wherein the said areas form, on each side of the sprocket/gear, a circular channel with constant section and with rectangular, wedge-like, dovetail-like or other profile.

15. The silent sprocket/gear according to claim 14, wherein the said through openings are equidistant through holes distributed in a concentric manner with respect to the centre of the sprocket/gear or the hub.

16. The silent sprocket/gear according to claim 13, wherein the elastic silencing member is radially extended inwardly i.e. towards the hub and the possible hole thereof, starting from a distance of about 1 mm measured from the base of the teeth.

17. The silent sprocket/gear according to claim 13, wherein the material of the silencing member is nitrile rubber NBR.

18. The silent sprocket/gear according to any claim 14, wherein the said area or said channel with constant section is extended in width for a minimum distance, corresponding for example to about cm and in any case it has a much smaller width than the primitive radius of the sprocket/gear that is of the radius measured from the centre to the circumference of the primitive circle.

19. The silent sprocket/gear according to any claim 13, wherein the said elastic silencing member forms a single rubber body, with rubber pins or members that pass through the through openings or the through holes.

20. The components for injection molding and vulcanization of the material forming the elastic silencing member in a sprocket/gear according to claim 1, wherein the said components comprise a first annular component and a second annular component each having a U-shaped cross section with a base and two sides or wings, so as to form a respective annular channel, said base of the annular channel of each component having a width substantially equal to that of the circular area or channel of the metal body of the sprocket/gear, and in that at least one of said components, for example the second component, has one or more holes for injecting the synthetic material to be vulcanized that will form the elastic silencing member.

21. The components according to claim 20, wherein they have grounded edges on their open part opposite the base of the annular channel, that is on the free ends of the sides of the U, in order to ensure optimal contact with the metal body and thus an optimal tight seal during the introduction of the synthetic material to be vulcanized in order to form the elastic 5 silencing member.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0021] The Figures show:

[0022] FIGS. 1-5: the sprockets of the known art, as well as their vulcanization methods, as described above;

[0023] FIGS. 6(a), (b): front and lateral view of a cross section of the sprocket (pinion) before its vulcanization, according to this present invention;

[0024] FIG. 7(a): perspective view of the cross section of the pinion according to the invention shown in FIG. 6, after its vulcanization;

[0025] FIG. 7(b): enlarged view of the detail highlighted by circle B in FIG. 7(a);

[0026] FIG. 8(a): similar view to FIG. 7(a), but with a channel (annular recess) of different shape;

[0027] FIG. 8(b): similar view to FIG. 7(b), but with a channel (annular recess) of different shape;

[0028] FIG. 9(a), (b): the invention mold and the vulcanization method according to the present invention, for the pinion in FIG. 7;

[0029] FIGS. 10(a), (b): a toothed crown silenced according to the present invention, viewed in a partial perspective view (cross section) and in an enlarged detail (as highlighted in circle A in FIG. 10 (a)) respectively;

[0030] FIGS. 11(a), (b) similar views to FIG. 10, but with a bilateral channel (annular recesses) of different profile or shape;

DESCRIPTION OF SOME CURRENTLY PREFERRED EMBODIMENTS

[0031] The present invention will be described purely as an example, and not in a limitative or binding way, using FIGS. 6 to 11 appended to this document, which concern exclusively the present invention. Such figures show some illustrative embodiments, but they aren't limiting or binding in any way regarding the present inventive concept.

[0032] In general, in the following of the present description, all details that are however obvious, or implicitly known, to the average man skilled in the art will be omitted. For example, the methods used to create the bilateral channels of the invention on the sprocket can be of different type, such that is not necessary to describe the manufacturing processes in detail. Also the materials used (different kinds of rubber to be used in the vulcanization of the sprocket or the sprocket material itself, such as quenched steel) can be adapted by the man skilled in the art to the specific application, in order to optimize the results achieved.

[0033] Also other technical details must be considered as known to the average man skilled in the art, and won't be treated here.

[0034] Furthermore, in FIGS. 6 to 11, as a simplification the same numerical references will be always used to indicate the same components of the claimed product.

[0035] In order to distinguish the present invention from the known art of FIGS. 1 to 5, all numerical references in FIGS. 6 to 11 will start from number 100.

[0036] FIG. 6 highlights the different structure of pinion 100 (according to the present invention) from the known art. Indeed, the through holes 104, equidistant and concentric, are now obtained in two circular recesses 200 (bilateral channel 200) obtained on the two surfaces (sections adjacent to teeth 105) of sprocket 100. By virtue of such circular channels 200 realized according to the invention in the corresponding tooth section (103a or 103b) of pinion 100, two circular steps (seen in the cross section of FIG. 6(a)) on the tooth sections 103a and 103b accordingly are created on each side of pinion 100. The corresponding surfaces (3a and 3b) of pinion 1 of the known art are otherwise smooth (see FIG. 1). As better described below, the aforesaid circular steps allow not having to depend on hub 102 for support.

[0037] FIG. 7 shows the invention pinion 100 after vulcanization and the effect created by the bilateral channel 200 according to the present invention. The housing (of a rectangular profile in cross section) for rubber 106 created by these circular recesses 200, absorbs the thrusts towards the inside (see arrows in FIG. 7(b)) thanks to the presence of the inner circular step 110. Said thrusts, caused by the chain inner plate (not shown), act on the circular cylindrical surfaces 109, but opposite to the toothed crown of the known art (FIG. 5), are now opposed by the inner circular step 110. Step 110, a few millimeters deep, receives such thrusts and is deep enough to sustain the pressure exerted by the chain on rubber 106. Hundreds of tests made in extreme conditions confirmed the total reliability of this system.

[0038] Even though (as in the known art) rubber 106 entering the through holes 104 during the injection molding forms a solid body, thus giving some retention effect of rubber 106 itself on sprocket 100, such effect doesn't allow, or is anyway insufficient for avoiding the compression of the rubber circular cylindrical surfaces 109 caused by the chain pressure.

[0039] FIG. 8 shows an alternative embodiment (or variant) of the present invention applied to pinion 100a in which the profile of the step that receives the chain pressure is wedge shaped. Such wedge shaped circular step, shown by number 100a in FIG. 8(b), allows optimizing the pressure absorption action exerted by the chain. Obviously, other types of profiles/cross sections of the bilateral channel 200 can occur to a man skilled in the art, without applying any inventive effort. All these variants are therefore comprised in the same inventive concept of the present invention. The two pairs of arrows in FIG. 8(b) indicate the transmission of forces towards the steps situated on the two respective sides of the silenced sprocket according to the present invention.

[0040] FIG. 8 also deals with a pinion with two lateral hubs, exactly like in FIG. 7.

[0041] In FIG. 9 (FIGS. 9(a) and 9(b)) the innovative mold and the vulcanization technique are shown, according to the present invention. These innovations are described in the application example concerning again pinion 100 for motorcycles, modified according to the present invention, that is with the bilateral channel 200. The bilateral channel allows for the vulcanization of only the surface where the rubber is required, thus allowing a considerable reduction of the rubber volume required. For example, vulcanizing the same identical pinion of FIG. 2 (which however lacks the bilateral channel 200) and achieving the same noise absorption, the volumetric value of the NBR rubber will be less in FIG. 9 (present invention) compared to the volume of NBR rubber of the traditional pinion 1 in FIG. 2. Therefore, according to the present invention (FIGS. 6,7,8,9), thanks to the presence of the steps created by the circular recesses 200, annular support surfaces are created for the rubber, which allow to reduce considerably the quantity of silencing material (rubber) used. The diameter and depth of the hub are inconsequential with this technology, therefore ignored. This allows to useaccording to the present inventionparticular molding devices (also simply named molds), as clearly shown in FIG. 9, which are more versatile since they don't depend (in contrast to the molding devices 7a,b of traditional type in FIG. 3) on the hub height/depth or its diameter.

[0042] Specifically, said molding devices 107a, 107b (FIG. 9) create channel-shaped rings (one of which with an injection hole 108) with width adapted to the width of the circular recesses 200, where the edges of the means 107a, 107b which are in contact with the surface of pinion 100 are rectified in order to ensure optimal tight seal during the injection molding.

[0043] In conclusion, in all cases (pinion in FIGS. 6 to 9), in contrast to the known art, the present invention allows to avoid the lateral rubber disks shown in FIG. 2, which extend to the hub in order to create a support base. This allows using less material (less pollution!) and more versatile and adaptable molds.

[0044] The advantages of the present invention are more obvious when this is applied to a motorcycle toothed crown (drive sprocket), and in general to sprockets lacking a central hub. The last figures, FIGS. 10 and 11, refer to this last issue. They show how toothed crown 100 and 100a respectively present a bilateral channel 200, or in other words two circular recesses 200 on the respective tooth sections (on both sides of the toothed crown).

[0045] The two toothed crowns 100 and 100a differ in the profile of the cross section of the channels (the first rectangular, wedge shaped the other). The respective enlarged details A of FIGS. 10(b) and 11(b) show the same functional principle and the same inventive concept enunciated and described before, but is important to note that in the case of a toothed crown (without a hub) the present invention permits for the first time to obtain a real silent sprocket, whose operation is guaranteed for a long period of time and in the case of a motorcycle amply exceeds the period required for the certification tests. This permits to prolong the toothed crown usage time period. A transmission block composed of O-ring chain and silenced sprockets (pinion and toothed crown) according to the technique of the present invention permits to reach noise values comparable to a belt transmission. Therefore also the noise containment efficiency is optimal.

Silenced Sprockets for Industry

[0046] The sprocket size can be larger, and their thickness greater than those of the sprockets dealt with up to now, therefore an infinite range of profiles (channels) can be used in order to optimize the rubber resistance. The noise in working environments with a high concentration of chain driven plants (product transportation-handling, manufacturing, packaging etc.) is annoying and often protested. The manufacturers of such plants are always busy developing increasingly silent systems. The possibility of supplying them with silenced sprockets is therefore a great opportunity to reduce the noise in working environments.

Invention System Advantages

[0047] 1. Maximized construction simplicity;

[0048] 2. A unique mold for a specific pitch and toothing (reduced mold cost);

[0049] 3. Total reliability both on a pinion (sprocket with a hub) and on a toothed crown (sprocket without a hub);

[0050] 4. Less pollution by reducing the volume of rubber required;

[0051] 5. The construction principle allows to produce silenced sprockets for the entire industrial field;

[0052] 6. Possibility of channel profile modification in order to increase the loads;