DE19707584A1 - Coupling unit for flexible shaft coupling - Google Patents

Abstract

The coupling unit for a flexible shaft coupling, to carry the torque transmission between two shafts, has a distance sleeve of a flexible material with mechanical strength, such as a thermoplastic elastomer or a thermoplastic which has been modified or has altered elasticity. The outer surface is structured with straight tooth splines on the axial direction. The material is pref. a thermoplastic polyester elastomer, a polyurethane elastomer or a thermoplastic with added talcum.

Description

The invention relates to a coupling element for flexible couplings the preamble of claim 1.

It is known to use flexible couplings for connecting two shaft ends a transmission of torque from the driving to the driven Use part if shaft misalignments are to be compensated. A major advantage of such flexible couplings is also in that he not only radial, axial and angular shaft misalignments can be worn, but due to an additional flexibility shocks and vibrations are damped in the circumferential direction, which is a enables smooth starting.

Endsei serve as coupling elements for such flexible couplings Interlocking coupling elements made of synthetic rubber, as with described for example in US 2,867,102. Has proven to be disadvantageous, however proved that the coupling elements of the known flexible coupling are molded parts that do not individually adapt to the respective  Allow connection relationships and their production is also expensive. For example, the length of a spacer sleeve is available on request and Specify order in advance.

The object of the invention is therefore a coupling element for a flexi ble clutch to create a compensation of shaft misalignments leaves, sufficiently compliant and more individual to each Shaft distance is adjustable.

This task is characterized by the characteristics of the characterizing part of the An spell 1 solved.

This creates a coupling element for a flexible coupling fen, which through the combination of material and form shape a formsta biles component of simple design delivers.

The spacer sleeve is inherently rigid due to the material and shape speed, which maintains shape and shape stability even at high turning speeds ensures moments and numbers. A guide of the spacer sleeve on ih The inside can therefore be omitted, in particular there is no inside tel gearing required with the known spacers in one Coupling half are additionally guided. The positive engagement with According to the invention, a coupling half takes place only via the external toothing sufficient to transmit torque. Hereby also simplifies the possibility of centering the inner di punching sleeve by means of a centering pin, so that the coupling element can be used without any problems even at high speeds.

The design advantages resulting from the choice of materials combined according to the invention with an outer casing toothing. The Coupling element can then be shortened and shortened simply by cutting to length can be individually adapted to different distances from connecting shaft ends. The outer jacket teeth ensure that a spacer sleeve shortened on one or both sides also has an end  Gearing has a positive engagement with a dome half allowed.

The use of a thermoplastic elastomer or either elastically modified or elastically filled thermoplastic, so Ma materials that, in addition to properties such as flexibility, elastic increase resilience and elasticity also good mechanical strength have the ability to produce spacer sleeves with length ren dimensions. On the one hand, larger shaft end distances are over bridgeable and on the other hand cuts of the coupling element by simp ch cutting of individual sections possible without the functional act of the coupling element is adversely affected. Relatively large Offsets between shaft ends are compensated by variable lengths bar, the coupling element due to its deformability forms a sufficiently elastic intermediate link that can be walked, so to speak.

The straight toothing of the outer surface preferably extends continuously, so with any cut for individual Length sizes the spacer sleeve ends have a toothing on the edge have positive engagement with the coupling halves.

The cross-sectional profile of the toothing can be selected. Prefers are axially extending toothed head beams with toothed profiles, such as set out in claims 4 to 7, which is an advantageous form allow grip with the coupling halves. Furthermore, it becomes a particularly good compensation of angular shaft misalignments achieved.

Ther are preferred as flexible material with mechanical strength Moelastic polyester elastomers or polyurethane elastomers. these are Elastomers that also have selectable Shore hardness and flexural modulus, such as preferably specified in claims 9 and 10, are adjustable. The Spacer sleeves are made of the thermoelastic elastomers mentioned special sprayable, pourable or extrudable. Thermo are also suitable plastics modified in this way or by adding additives or  Fillers are changed in their properties so that they are a good Er recovery after compression or tensile deformation so that they have a high survive the number of bending cycles.

To improve the end stiffness of the spacer sleeve, in particular at high torques and / or high temperatures if the ver plastic material that tends to become soft can be a Support bushing can be inserted into the spacer sleeve. This support socket be acts that a possible backlash by avoiding a tooth flange is minimized. The use of spring steel is preferred for the formation of a preloaded support bush.

Further embodiments of the invention are described below exercise and the subclaims.

The invention will now be described with reference to the accompanying figures illustrated embodiments explained in more detail.

Fig. 1 shows a cross section schematically showing a first embodiment of a coupling element in the form of a spacer sleeve,

Fig. 2 shows enlarged a section of the cross section according to Fig. 1,

Fig. 3 shows schematically a longitudinal section of the collet of FIG. 1,

Fig. 4 is a plan view schematically showing an attachable to a shaft end coupling half for a positive engagement with the spacer sleeve according to Fig. 1 to 3,

Fig. 5 shows in cross section a form-locking engagement of the collet shown in FIG. 1 to 3 with the coupling half according to Fig. 4,

FIG. 6 shows a cross section according to AA according to FIG. 4,

Fig. 7 shows in cross section a form-locking engagement of a spacer according to a second execution example with a coupling half,

Fig. 8 shows schematically a cross-section of a third embodiment of a coupling element in the form of a spacer sleeve,

FIG. 9 schematically shows a longitudinal section of the spacer sleeve according to FIG. 8.

Figs. 1 to 3 show a first embodiment of a coupling element for a flexible coupling for connecting two shaft ends. The coupling element is formed by a spacer sleeve 1 . The Di punch sleeve 1 is with a selectable outer diameter D (ring gear diameter) as well as with a selectable inner diameter I ( Fig. 1) and with a selectable length L ( Fig. 3). Usual outer diameters D are in the range from 40 to 400 mm.

The lengths L can be selected according to requirements and range from a few centimeters to the meter ranges. Preferred overall lengths L are in the range from 30 to 1000 mm. By cutting axial part pieces, the spacer sleeve 1 can be shortened variably.

The spacer sleeve 1 consists of a highly stressable elastic construction material, which is formed from a thermoplastic elastomer or a thermoplastic that is either elastically modified or elastically modified by fillers. Thermoplastic polyester elastomers, such as Hytrel from Dupont, or polyurethane elastomers with the trade name Vulkolan are preferred. Thermoplastics that are modified or modified by fillers or additives in such a way that they show a good recovery after compression or tensile deformation can also be used. As such an additive is known in particular talcum, which can be added in amounts of 10-20 wt .-% thermoplastics to give them the desired flexibility and elastic recovery.

The aforementioned flexible materials with mechanical strength Shore hardness is preferably in the range between 40 and 72 D, in particular 45 to 65 D, used. The construction used material is in the hardness range between the rubber-elastic work fabrics and hard plastics. The bending moduli are preferably in the range of 100 to 300 MPa.

The spacer sleeve 1 can in particular be injection molded, cast or extruded from these materials.

The shape of the spacer sleeve 1 is tubular. The tubular spacer sleeve 1 is formed by a tooth (basic) ring 2 with an outer toothing which is formed by an outer surface 3 with straight teeth in the axial direction X. The straight toothing comprises circumferentially arranged tooth head beams 4 , which extend axially over the entire length L of the spacer sleeve 1 . Preferably, the tooth head bars 4 extend continuously over the entire length L. Alternatively, not shown incisions or recesses can interrupt the tooth head balls 4 in the axial direction X. The tooth head bar 4 comprise in the radial direction tooth feet 5 with attached tooth heads 6 , the flanks of which are preferably formed in the shape of a circular arc, in particular with a flat, round cross section. Alternatively, the tooth heads 6 can be pointed, rounded or flattened on the tooth flanks of the tooth feet 5 , as is shown, for example, in the second embodiment of the spacer sleeve 1 according to FIG. 7.

The number of tooth head bars 4 arranged around the circumference can be selected depending on the outer diameter A and a width of the tooth feet 5 . A gap of 7 can also be selected. The radial Gesamtterstrec tion of the tooth base 5 and the tooth head 6 of a tooth head beam 4 is to be selected such that a reliable torque transmission takes place.

The radial thickness of the ring gear 2 can be relatively small and is preferably substantially equal to the total radial height of the tooth head beam 4 from the tooth base 5 and tooth head 6 or can be 1 to 1.5 times this total height of the tooth head beam 4 .

The spacer sleeve 1 also preferably has a cross-sectional area that is constant in the axial direction X and has a toothing-free inner jacket surface 8 . This inner lateral surface 8 can be smooth, grooved or structured differently. The inner lateral surface 8 forms the inner boundary of the ring gear 2 .

As an alternative to the exemplary embodiment illustrated in FIGS . 1 to 3, where the ring gear 2 has a constant radial thickness in the axial direction, the ring gear 2 can also have varying radial thicknesses in the axial direction X. Finally, the ring gear 2 can be round or angular on the inside.

Spacer ends 9 , 10 of the spacer described above can be brought into positive engagement with the coupling halves 11 , one of which is shown in FIGS. 4 to 6, via the external toothing 3 . The extending over the entire length L of the spacer sleeve 1 outer edge toothing 3 ensures that even with shortened by separating axial sections spacer sleeves 1 in the loading range of the spacer sleeve ends 9 , 10 there is a toothing.

The coupling half 11 comprises a connector 12 , with which the hitch be half 11 can be fastened to a shaft end, in particular by wedging or flanging, and a clutch disc 13 which carries an edge-side negative mold 14 for the teeth 3 of the spacer sleeve 1 . As shown in FIG. 5, the negative form 14 of the coupling half 11 and the outer toothing 3 of a spacer sleeve 1 inserted into the coupling half 11 interlock positively. An inner guidance of the spacer sleeve 1 is not necessary.

The axially straight-toothed outer circumferential surface 3 causes in the area of the clutch disks 13 and the negative form 14 an axial extension of the engagement by means of the toothed head beam 4 , which has an influence on the specific surface pressure on the tooth (head) and the specific tooth load (bending and Shear stress).

According to a further embodiment, not shown, the coupling half 11 can have a centering pin which projects into the spacer sleeve 1 and ensures that the spacer sleeve is centered internally at high speeds.

Fig. 7 shows a second embodiment of the spacer sleeve 1 and the associated coupling half 11 , which differs from the above-described embodiment only by a different shape of tooth head 6 and tooth base 5 . Depending on the choice of the shape of tooth head 6 , tooth base 5 on the spacer sleeve 1 and the shape of the negative mold 14 , the positive engagement between the spacer sleeve 1 and coupling half 11 can also be limited to tooth flanks 17 , as shown in FIG. 7.

FIGS. 8 and 9 show a third embodiment of a coupling element in the form of a spacer sleeve 1, which differs from the above embodiments be written that in the di punch bushing 1 is a support bushing 18 is inserted. The support bushing 18 is inserted at the end of the end 9 and extends over an axial section of the length L of the spacer sleeve 1 . The support bushing 18 is preferably formed from a spring steel with an axially continuous gap 19 . Such a support bushing 18 , as a prestressed bushing, can improve the form fit in the toothing of the spacer sleeve 1 . The support bushing 18 can be inserted on one or both sides of the spacer sleeve 1 and is supported on the circumferential side on the inner surface 8 of the spacer sleeve 1 .

According to a further embodiment, not shown, the Di stamping sleeve have toothed head beams made of a different flexible Ma material with mechanical strength than the ring gear. Preferential  then such a material with a lower Shore hardness and such a material for the sprocket or other composition, with a higher Shore hardness det.

Claims (12)

1. Coupling element for a flexible coupling for connecting two wel lenenden in the form of a spacer sleeve made of a flexible material, the spacer sleeve ends have a toothing for a positive engagement with a coupling half attachable to a respective shaft end, characterized in that the spacer sleeve ( 1 ) from a consists of flexible material with mechanical strength such as a thermoplastic elastomer or an either elastically modified or elastically modified thermoplastic and has an outer surface ( 3 ) geared in the axial direction (X). 2. Coupling element according to claim 1, characterized in that an inner circumferential surface ( 8 ) of the spacer sleeve ( 1 ) is toothless. 3. Coupling element according to claim 1 or 2, characterized in that the spacer sleeve ( 1 ) has a constant in the axial direction (X) ausgebil Dete cross-sectional area. 4. Coupling element according to one of claims 1 to 3, characterized in that the straight-toothed outer circumferential surface ( 3 ) is formed by a toothing of axially extending toothed head beams ( 4 ), de ren flank profiles ( 17 ) are formed in a circular arc. 5. Coupling element according to one of claims 1 to 4, characterized in that the spacer sleeve ( 1 ) comprises a ring gear ( 2 ), the height of which is substantially equal to the height of the teeth of the outer surface ( 3 ). 6. Coupling element according to one of claims 1 to 5, characterized in that the teeth of the outer circumferential surface have tooth tips ( 6 ) which taper, rounded or flattened on tooth flanks of tooth feet ( 5 ). 7. Coupling element according to claim 6, characterized in that the tooth head beams ( 4 ) have a flat round cross section. 8. Coupling element according to one of claims 1 to 7, characterized records that as a flexible material with mechanical strength thermoplastic polyester elastomer, a polyurethane elastomer or a thermoplastic mixed with talc as an additive is provided. 9. Coupling element according to one of claims 1 to 8, characterized records that the Shore hardness of the flexible material with mechanical Strength in the range between 40 and 72 D, in particular 45 to 65 D, lies. 10. Coupling element according to one of claims 1 to 9, characterized in that the spacer sleeve ( 1 ) consists of a material with a Bie ge-E module in the range between 100 and 300 MPa. 11. Coupling element according to one of claims 1 to 10, characterized in that the spacer sleeve ( 1 ) on one or both sides has an end-seated and extending over an axial section portion inner support bushing ( 18 ). 12. Coupling element according to claim 11, characterized in that the support bush ( 18 ) consists of spring steel and resiliently biased against an inner circumferential surface ( 8 ) of the spacer sleeve ( 1 ).