NL9400224A - Assembly of at least a first and a second cylindrical element, and element provided with projections which are suitable for use in an assembly of this nature - Google Patents

Abstract

The invention relates to an assembly of at least a first and a second cylindrical element, the first element lying coaxially inside the second element, and at least one of the two elements being provided with at least three projections which are directed radially towards the other element and are distributed regularly, as seen in the tangential direction, along the periphery of the element, the projections bearing against the other element so as to elastically deform at least one of the two elements.

Description

Short designation: Assembly of at least a first and second cylindrical element, as well as an element provided with projections suitable for use in such an assembly.

The invention relates to an assembly of at least a first and second cylindrical element, the first element being located coaxially in the second element.

The invention also relates to an element suitable for use in such an assembly.

Such an assembly usually includes a shaft or sleeve as the first element and a sleeve slid over it as the second element, which are releasably connected and aligned with one another to transmit rotational motion from one element to another . Such assemblies are known, inter alia, from "Dubbel Taschenbuch für den Maschinenbau", 15th edition, 1986, pages 403 to 407, section 3.2 "Wellen-Naben-Verbindungen", in particular Figures 5 and 6 ".

The disadvantage of the form-fit connections shown in Fig. 5 and the friction-fit connections shown in Fig. 6 is that most connections require additional parts to connect two cylindrical elements, the cylindrical elements having to be manufactured relatively accurately for accurately centering the two elements relative to each other. Both the additional parts required and the required precise fabrication of the elements make these connections relatively expensive and complicated.

If the internal diameter of the second cylindrical element and / or the external diameter of the first cylindrical element are relatively inaccurate, it is relatively difficult to align the centerlines of the two elements with respect to each other. This is obviated in the connections as shown in Fig. 6 H-M by means of elastically deformable intermediate elements, which are clamped between the first and second element and which absorb the diameter tolerances by means of a self-adjusting elastic deformation. The drawback of the intermediate elements shown in Fig. 6 H-M is that they must be manufactured as an additional part and that the first and / or second element must also be provided with local rejuvenations or a chamber in which the intermediate element must be fitted. Therefore, the H-M shown in Fig. 6 are relatively complicated.

The object of the invention is to provide an assembly in which the elements are aligned and connected in a simple manner relative to each other.

This object is achieved in the assembly according to the invention in that at least one of the two elements is provided with at least three protrusions, radially directed towards the other element, which are regularly distributed along the circumference of the element, seen in tangential direction, wherein the protrusions abut the other element under elastic deformation of at least one of the two elements.

The diameter of a descriptive cylinder of the protrusions if the second element is provided with the protrusions is smaller than the diameter of the first element and if the first element is provided with the protrusions larger than the internal diameter of the second element. The centerline of the descriptive cylinder coincides with the centerline of the element comprising the protrusions. When aligning and joining the assembly, the first element is slid axially into the second element, with the protrusions or the other element displaced in a radial direction so that the protrusions lie against the surface of the other element. Since an element is provided with at least three protrusions, which are arranged regularly along the circumference, the protrusions will each exert an almost equal force on the other element, so that the other element is moved through the protrusions relative to the element comprising the protrusions aligned. No additional intermediate elements are required with the assembly according to the invention.

An embodiment of the assembly according to the invention is characterized in that the element comprising the protrusions is elastically deformed between the protrusions.

When the protrusions are moved in a radial direction, the spacing of the protrusions changes. This change is compensated for by an elastic deformation of the element between the protrusions. The distance between the protrusions will generally be greater than the size of the protrusions in the tangential direction, so that a deformation can more easily be elastically absorbed by the element located between the protrusions than by the protrusions themselves.

Another embodiment of the assembly according to the invention is characterized in that the element comprises a number of rows of protrusions in the axial direction.

This centers the two elements relative to each other over the entire axial length of the assembly.

Another embodiment of the assembly according to the invention is characterized in that the sleeve-shaped second element comprises the protrusions, the protrusions being indentations directed towards the center line in the element.

Such protrusions can easily be placed in a sleeve.

A further embodiment of the assembly according to the invention is characterized in that the axis- or sleeve-shaped first element comprises the protrusions, the protrusions being protuberances away from the center line of the element.

Projections can be arranged on the first element in the same simple manner.

A still further embodiment of the assembly according to the invention is characterized in that the protrusions are ribs extending in axial direction.

A rib hereby forms, as it were, a contiguous row of protrusions in the axial direction, wherein the rib can easily be arranged in the element.

Another embodiment of the assembly according to the invention is characterized in that the element, comprising the protrusions, is provided with at least two discs, the edges of which face the other element are bent in the same axial direction, the bent edges being elastic in the radial direction. deformable protrusions.

If the outer diameter of the first element is considerably smaller than the inner diameter of the second element, a connection between the first and second element can be formed by means of the disks, the disks also ensuring an alignment of the first and second elements in that the edges of the discs comprise the projections elastically deformable in the radial direction. The edges themselves can form the projections or the edges can be provided with separately arranged projections. Both the first and second elements, as well as the discs, are easy to manufacture and the assembly is easy to assemble. If the edges, in tangential direction, abut the other element over the entire circumference, the edges form a continuous chain of projections.

A further embodiment of the assembly according to the invention is characterized in that the edges are provided with radial cuts, whereby the disc is divided into segments which can be elastically deformed independently of one another.

Due to the segments that can be moved independently in radial direction, larger diameter tolerances can be accommodated under elastic deformation of the edges.

A further embodiment of the assembly according to the invention is characterized in that both elements are provided with projections placed against each other, the elements being rotatable relative to each other for positioning the projections against each other and translatable in axial direction for sliding the elements in or out of each other, the projections of the different elements being juxtaposed by rotation in tangential direction.

This results in an assembly in which the elements can be positioned in an axial direction relative to each other with a relatively small force, after which the elements are rotated relative to each other, whereby the protrusions of the different elements are brought together. When the elements are pushed together, the protrusions, viewed in tangential direction, lie next to each other, so that they can slide past each other. If the descriptive diameter of the first element with protrusions is less than the internal diameter of the second element without protrusions, and the inscribed diameter of the second element with protrusions is greater than the diameter of the first element without protrusions, then the elements can be powerless are pushed together. However, the inscribed diameter of the second element with protrusions should be smaller than the descriptive diameter of the first element with protrusions, so that after rotation of the first element relative to the second element the protrusions are positioned opposite each other under an elastic deformation of at least one of the two elements.

Another embodiment of the assembly according to the invention is characterized in that the elements are detachably attached to each other by means of fastening means.

In order to prevent mutual rotation of the first and second element when transmitting a rotational movement of one or the other element, the elements can be fastened to each other by means of fastening means known per se.

The invention is explained in more detail with reference to a drawing, in which, Figures 1A and 1B, respectively. a cross-section and front view of a first embodiment of an assembly according to the invention, Figs. 2A and 2B, respectively. a cross-section and front view of an element according to the invention of the assembly of fig. 1A and 1B, fig. 3 shows a pattern of protrusions, as applied to the element shown in fig. 2A and 2B, fig. 4 a cross-section of a second embodiment of an assembly according to the invention, fig. 5 shows an element according to the invention, of the assembly of fig. 4, fig. 6 shows a cross section of the third embodiment of an assembly according to the invention, fig. 7 shows an element according to the invention of the assembly of fig. 6, fig. 8 shows a front view of a fourth embodiment of an assembly according to the invention, fig. 9 shows a detail of the assembly shown in fig. 8, fig. 10A and 10B resp. a front and side view of a second embodiment of a disc of the assembly shown in Fig. 8, Figs. 11 and 11B, respectively. a front and side view of a third embodiment showing a disk the assembly shown in Fig. 8.

Corresponding parts are designated with the same reference numerals in the various figures.

Fig. IA and 1B show resp. a cross-section and front view of an assembly 1 which is provided with a first metal can-shaped element 2 and a second metal can-shaped element 3, which are coaxial with each other with a common axis 4. The second element 3 is over the whole circumference provided with indentations 5 which form projections radially directed towards the first element 2. The first element 2 has an external diameter d. The second element 3 has an inscribed diameter D1 and without the protrusions 5 a diameter D2 (see Fig. 2A and 2B). For the diameters, D2> d> Dl. The diameters d, D1, D2 apply to the elements 2, 3 in a non-composite state. When the elements 2, 3 are slid together in axial direction, the dimples 5 abut against edge 6 of the first element 2, the dimples 5 being placed radially away from the center line 4 under an elastic deformation of the second element 3 The first element 2 will hardly deform, since the wall thickness W1 of the first element 2 is relatively thick relative to the wall thickness W2 of the second element 3. The indentations 5 in the second element 3 are relatively rigid with respect to the other material of the second element 3, because an indentation 5 has a relatively small surface area and is bounded by reshaped and thus reinforced edges 7. The elastic deformation of the second element 3 will thereby be absorbed by the material of the second element located between the indentations 5 2. By arranging the indentations 5 at a distance as regular as possible, the elastic deformation is regularly spread over the second e element distributed. When the two elements 2, 3 are pushed together, in the case of an elastic deformation of the second element 3, forces are exerted by the indents 5 on the first element 2 in the direction of the center line 4, the first element 2 being radially moved until the forces of the indentations on the first element 2 are almost equal. The second element 3, along the periphery, seen in tangential direction, is provided with six indentations which exert a force on the first element 2 in the direction of the center line 4, whereby the first element 2 is aligned with respect to the second element 3. The greater the number of indentations along the circumference, the more accurately the first element 2 is aligned relative to the second element 3 and diameter tolerances are accommodated. In an entrepreneur's assembly according to the invention d = 108 mm, D1 = 107 mm and D2 = 110 mm.

The second element 3, viewed in axial direction, is provided with a number of rows of indentations 5, so that the elements 2, 3 are aligned along the entire axis 4. The dimples 5 are made by means of stamps in the second element 3, whereby the dimples 5 can be fitted while the second element 3 is already bush-shaped or the dimples 5 can be placed in sheet material, after which the sheet material is rolled up and edges thereof are joined welded to obtain a bush.

Fig. 3 shows a knocked-out pattern 8 of dimples 5 as arranged in the second element 3 of FIGS. 2A and 2B. The rectangular indentations 5 are regularly distributed over the surface of the second elements 3 and are symmetrically opposed to the centerline 4.

Figures 4 and 5 show a second embodiment of an assembly 1 and element 2 according to the invention. In this embodiment, the first sleeve-like element 2 is provided with protuberances 9, which are arranged in the first element 2 in a similar manner as described above. The first element 2 has a defining diameter d1 and without protuberances 9 a diameter d2. The second element 3 has its internal diameter D. For the diameters it holds that d1> D> d2. The wall thickness of the first and second element 2, 3 is resp. W1 and W2, where W1 is relatively large compared to W2. When the elements 2 and 3 are pushed together in the axial direction, the projections 9 in particular will elastically deform the second element 3,

Figures 6 and 7 show a cross section of a. third embodiment of an assembly 1 and element 3 according to the invention, wherein the second element 3 is provided with indentations 5 and the first element 2 is provided with protuberances 9, which are arranged in the same pattern in the elements 2, 3. The first element 2 is identical to the first element 2 shown in Fig. 5. For the diameters of the elements 2, 3 it holds that: D2> dl> D1> d2. When the elements 2, 3 are slid together in axial direction, the protrusions 9 and the indentations 5, seen in tangential direction, are placed next to each other, so that the elements 2, 3 can be moved freely in axial direction with respect to each other, since d1 <D2 and Dl> d2. After the elements 2, 3 are positioned in axial direction relative to each other, the second element 3 is rotated relative to the first element 2 in the direction of arrow R, until the dimples 5 rest on the protrusions 9 under elastic deformation of the elements 2, 3.

Fig. 8 shows a fourth embodiment of an assembly 1 according to the invention, wherein the first shaft-shaped element 2 is provided with two discs 10 which are fixedly connected to the first element 2 by means of a welding seam 11. The diameter d2 of the first element 2 is considerably smaller than the internal diameter D of the second element 3. Of the discs 10, edges 12 directed towards the second element 3 are bent in axial direction, before the first element 2 in the second element 3 has been pushed. The bent edges 2 have an external diameter d1 which is larger than the internal diameter D of the second element 3.

Fig. 9 shows an enlarged detail IX of FIG. 8, the edge 12 of the disc 10 being drawn in an unassembled position with a second element 3, but drawn in overlapping position to clearly represent the diameters d1 and D.

When the elements 2, 3 are slid together in the axial direction, the edges 12 bend in a radial direction under an elastic deformation until the diameter d1 of the discs 10 is equal to the internal diameter D of the second element 3. Because the edges 12 along the entire circumference, viewed in tangential direction, are deformed in radial direction, the two element 2, 3 are precisely aligned with respect to each other. The edge 12 forms, as it were, a continuous chain of protrusions. The disc 10 is then connected to the second element 3 by means of a welding seam.

Figures 10A and 10B show respectively. a front and side view of a second embodiment of a disc 10 according to the invention, which can be used in the assembly 1 shown in Fig. 8. The disc 10 is provided with a hole 13 in which the first element 2 can be slid and further includes six protrusions 14, with only the protrusions 14 abutting the second element 3 in an assembly 1 under elastic deformation of the edge 12 of the disc 10.

Fig. 1 IA and 11B show resp. a front and side view of a third embodiment of a disc 10 according to the invention. In the disc 10, six radial cuts 15 are made, whereby the disc 10 is divided into six segments 16, the edges 12 of which are independently deformable in the radial direction, independently of each other.

In the embodiments as shown in Figs. 1A, 1B, 4, 5, 6, it is also possible to use a shaft as the first element 2, wherein in the embodiments of Figs. 4, 5, 6 protuberances are provided on the shaft , for example screwed or welded caps.

The first and second elements can be made of metal, plastic or other elastically deformable materials.

The pattern of protrusions can be arbitrary and can be determined experimentally.

The protrusions can be not only rectangular, but also circular, spherical or rib-shaped.

The elements 2, 3 can be releasably attached to each other with the aid of a bolt to prevent mutual rotation when transferring a rotational movement from one element to the other. If the elements are releasably connected, the element can be easily replaced.

The assembly according to the invention is particularly suitable for elements whose diameters are relatively inaccurate.

Claims (11)

An assembly of at least a first and second cylindrical element, the first element being located coaxially in the second element, characterized in that at least one of the two elements is provided with at least three radially directed towards the other element protrusions regularly distributed in tangential direction along the circumference of the element, the protrusions abutting the other element under elastic deformation of at least one of the two elements. Assembly according to claim 1, characterized in that the element comprising the protrusions is elastically deformed between the protrusions. Assembly according to any one of the preceding claims, characterized in that the element comprises a number of rows of protrusions in the axial direction. Assembly according to any one of the preceding claims, characterized in that the sleeve-shaped second element comprises the protrusions, the protrusions being indentations directed towards the center line in the element. Assembly according to any one of the preceding claims, characterized in that the axis- or sleeve-shaped first element comprises the protrusions, the protrusions being protuberances away from the center line. Assembly according to any one of the preceding claims, characterized in that the protrusions are axially extending ribs. Assembly as claimed in any of the foregoing claims, characterized in that the element, comprising the protrusions, is provided with at least two discs, the edges of which face the other element are bent in the same axial direction, the bent edges the radial direction. elastically deformable protrusions. Assembly according to claim 7, characterized in that the edges are provided with radial cuts, whereby the disc is divided into segments which are elastically deformable independently of one another. Assembly according to any one of the preceding claims, characterized in that both elements are provided with protrusions positioned against each other, the elements being rotatable relative to each other for positioning the protrusions against each other and being translatable in axial direction for sliding the elements in or out, the projections of the different elements being juxtaposed by rotation in tangential direction. 10. An assembly according to any one of the preceding claims, characterized in that the elements are detachably attached to each other by means of fastening means. Element provided with projections suitable for use in an assembly according to any one of the preceding claims.