DE2655517A1 - Positive connector for telescoped pipes - has groove in outer pipe provided with conical face to maintain tension in joint - Google Patents

Abstract

The positive connection is for two elements, esp. pipes, which partly cover each other, and each have a groove in facing surfaces. The groove is deeper in one pipe, and both accommodate a common connection element, which transmits forces, directed at right angles to a surface containing the grooves. The side (8) of the connection element (3) engaging, during a load, on the flank (6) of the deeper groove (4), is inclined relative to the direction of force (F) by an angle (alpha). When compared to the corresponding angle (Beta) with engagement of the side (11) of the connection element on the flank (10) of the flat groove (5), the angle (alpha) is larger, so causing a transverse force (Q) to act onto the connection element, positioning it in the flat groove.

Description

Positive connection between two parts, especially cylindrical

drischer parts The invention is concerned with a form-fitting Compound of the type specified in the preamble of claim 1.

The connection of cylindrical components is known, for example two partially nested tubes, with the help of snap rings, which for the assembly can be expanded or compressed radially. Disadvantageous with this one positive connection is that the two components for receiving the A circumferential groove, provided by the snap ring, takes up a relatively large amount of space, since one of the two must have such a depth that it widened during assembly or is able to accommodate compressed snap ring. This type of connection is therefore only applicable for components with a correspondingly large wall thickness.

It is also known, two cylindrical components by means of a To connect wire with a rectangular or circular cross-section. This is in the components to be fixed against each other, partially pushed one on top of the other A circumferential groove is screwed into each of the surfaces that are turned towards one another, so that it bears are that in the annular space formed by the opposing grooves Wire can be pushed in via a filling opening. The fill opening is one opening formed in the outer or inner component, which is connected to one of the two. Grooves is connected and pushing the wire through as a common connection element the two parts made possible.

The grooves are perpendicular to the direction of load, i.e. in the case of cylindrical ones Parts formed in radial planes extending flanks. The required The groove depth is smaller here than with the aforementioned snap rings, but it can still be too large depending on the wall thickness of the components. The reason for this is that the manufacturing tolerances require a minimum groove depth, to prevent accidental loosening of the connection, and continue to do so relatively large groove depths must be provided in order to ensure that in each individual case to ensure the required load-bearing capacity. It must also be taken into account that the common connecting element in the two gluten does not have a defined position occupies, so that it is sometimes more in one groove and sometimes more in the other to wear comes.

The invention is based on the object of a form-fitting Compound of the type specified in the preamble of claim 1, in particular the above Avoid disadvantages, i.e.

; to train these in such a way that a .defined Position of the connecting element in the grooves is achieved, especially in thin-walled components with a correspondingly small or even very small groove depth to achieve the highest possible load-bearing capacity of the connection.

The two parts to be connected to one another are especially around cylindrical bodies, at least one of which is partially or also is designed entirely as a hollow cylinder, to it more or less far on the other To be able to push the body. The cross section is generally circular, can but e.g. also oval or curved in some other way, whereby the direction of the Curvature can in principle also change. This form-locking connection can also can also be used for bodies curved in two planes, e.g. in the connection area Curved tubes pushed one on top of the other, hemispherical shell-shaped Bodies or the like. Furthermore, the cross section of the body can also be regular or irregular Polygon, e.g.

Triangle, rectangle or octagon. The only requirement is that the both parts can be pushed one above the other in the connection area. There are then if necessary, several grooves with associated filling openings distributed over the circumference to be provided. Finally, flat, curved, angled or the like can also be used. flat Bodies such as plates that overlap in the joint area in this way be connected to each other, provided that it is ensured, e.g. through from others Reasons necessary lateral guides, brackets or the like. That they are not vertical to their areal expansion or in the direction of the positive connection, i.e. in Groove direction can be moved apart.

The form-fitting connection according to the invention is used for receiving t of tensile or compressive loads, under the action of which the two parts with themselves opposite groove flanks are pressed against the common connecting element. Cylindrical parts are longitudinal or axial forces that are perpendicular are directed to the cutting plane containing the connecting element. The grooves are preferably formed undercut-free.

According to the invention, the aforementioned object is achieved by the characteristics in of claim 1 specified training solved. This is advantageous a desired positioning of the connecting element achieved under load, so that this inevitably rests on the bottom of the groove whose depth is less, thus the disadvantageous influence of the manufacturing tolerances with regard to the flatter groove is essentially eliminated. This can also be used for structural reasons very shallow groove depths in one part, connections with high load-bearing capacity are reliable be realized.

The difference in the angle of inclination C; and ß is preferably straight chosen so large that the resulting shear force is sufficient, about the friction between the two parts and the connecting element as well as possibly to overcome its bending stiffness, and so the connecting element against the flatter Press groove. An unnecessarily large angle difference with a correspondingly larger one Lateral force causes an increased lateral load on the part with the flatter one Groove, which is generally not in view of the small wall thickness of this component is appropriate.

t) the connecting element preferably has a circular cross-section on, but it can in principle also be an oval, rectangular, square or the like. Have cross-section. The formation of the grooves depends on the shape of the connecting element vote in order to achieve the application of force according to the invention on the connecting element. In the case of an element with a circular cross-section, for example, it is vertical the groove flank resting against it when it is touched, the so-called load-bearing flank, required that these with their outer edge or

- viewed in section across the grooves - with their outer corner rests on the connecting element to the angle of inclination required according to the invention opposite the tangent on the connecting element at the point of contact with the load-bearing flank of the verticals to be realized, with vertical supporting groove flank and for example It is a connecting element with an angular cross-section for the same reason required, at least at the point of contact of the corner of the load-bearing flank of the lower one Groove the connecting element to provide a correspondingly inclined side surface, around - viewed in a section across the grooves - the deliberate decomposition of the load force acting on the connecting element in a component transverse to it and to achieve a component perpendicular to the side surface.

The connecting element is preferably used as a wire, strand or the like.

made of steel, non-ferrous metal or plastic, for example, which is pushed into the opposing grooves via the filling opening. Instead, however, it could, for example, also be introduced into the grooves as several successively Sections of wire, balls or another engaging in both grooves that Power transmission between the two parts ensuring shape are formed.

In an advantageous embodiment of the invention it is provided that the load-bearing The flank of the deeper groove is no longer to be arranged vertically, but in the contact area with the connecting element to form the angle inclined from. The flank can for this purpose, for example, be designed as a concave or convex curved annular surface, the tangent of which at the point of contact with a connecting element with, for example, circular Cross-section has the required inclination. For a fastener with a the straight side inclined obliquely by the angle 6 is then at least the load-bearing flank in the area of contact with this side also as a straight line inclined by the angle s, always viewed in section across the grooves, formed. This training has opposite the vertical groove flank with the outer corner as a contact point on Connecting element has the advantage that the contact is now in the area of the flank surface takes place, whereby the basic strength of the materials is possible depending on the load Deformations of the connecting element or the groove flank can be reduced.

According to the invention it is also provided in an analogous manner the supporting flank of the flatter groove in the contact area with the connecting element to form the angle ß inclined.

In this case, there is a connection element with a curved one Cross-sectional outline in the contact area compared to an installation in the outer corner the shallower groove on the connecting element has the additional advantage that the distance the point of contact between the load-bearing flank and the connecting element and the groove base is lower is what relates to the stress on the component on bending by the loading force is advantageous so that the Part with the flatter groove in their Area can optionally be formed with an even smaller residual wall thickness. Another Advantage of the inclined design in the contact area or point of both load-bearing Groove flanks is that the connecting element is not on the outer groove edges with may set very high specific surface loads.

According to a further proposal of the invention, the load-bearing is preferred Flank of the deeper groove and preferably also that of the shallower groove - in cross section considered - designed as an inclined straight line, e.g. to reduce the effort for the Keeping groove production as low as possible. Since the groove or grooves are preferably free of undercuts are, these straight lines are inclined so that the clear cross-section of the groove increases from the groove base to its open end.

The invention is shown in the drawing in exemplary embodiments and is explained in more detail below on the basis of this.

It shows in cross section: FIG. 1 a connection with vertical supporting groove flanks Fig. 2 shows a connection with an inclined supporting groove flank and FIG. 3 shows a connection in which both supporting groove flanks are inclined.

In the connection shown in Fig. 1, the part 1 is with the part 2, both of which are only shown in detail, over which a pentagonal cross-section having connecting element 3 positively connected. On parts 1 and 2 acts on a longitudinal force, which is indicated by the arrows F. in the Part 1 is the deeper groove 4 and part 2 is the shallower groove 5. The vertical load-bearing flank 6 of the deeper groove 4 lies with its outer corner 7 on the side surface 8 of the connecting element 3. The side surface 8 is opposite the vertical 9 inclined by the angle d of about 300.

In the shallower groove 5, the supporting flank 10 is also perpendicular arranged and lies fully on the opposite side surface 11 of the connecting element 3, so that the angle of inclination β is here Oo. The connecting element 3 is therefore pressed with the transverse force Q against the base 12 of the flatter groove 5 and in this is positioned.

Via the circular cylindrical part 1 shown in detail in FIG. 2 is the part 2 with its hollow cylindrical extension 13 with a wall thickness d of for example 0.75 mm pushed with little radial play. Parts 1 and 2 made of steel, for example, are so positively connected that the through the arrows F indicated tensile load is transmitted properly. These are the Parts 1 and 2 with their facing surfaces 14 and 15 emanating circular grooves 16 and 17, respectively, in which the common connecting element 18, e.g.

a steel wire with a circular cross-section, engages positively. The groove 16 is deeper than the groove 17. The one under the contact F on the connecting element 18 adjacent load-bearing flank 19 of the groove 16 is opposite the perpendicular 20, which is also directed perpendicular to the load F, inclined by the angle dS so that the Width b of the groove 16 increases from the groove base 21 to the surface 14, i.e. towards the open end. The flank 19 is here - viewed spatially - designed as a conical surface. the supporting flank 22 of the opposite flatter groove 17 is in a known manner directed perpendicular to the groove base 24 or the load F. At the point of contact of the Corner 25 of the supporting flank 22 of the groove 17 on the connecting element 18 forms the tangent 26 on the connecting element 18 with the perpendicular 20 the angle β. Since the angle dL is greater than the angle β, the connecting element 18 is under the load F is pressed with the transverse force Q into the flatter groove 17 so that it is at the bottom of the groove 24 and the corner 25 of the supporting flank 22 rests in the connection shown in FIG. 3 the groove 16 of the part 1 is formed in the same way as in Fig.2. Additionally are exemplary two other shapes curved in two planes the supporting flank 19 indicated. The dashed curve 27 represents a flank with an increasing angle of inclination oU from the groove base 21 to the open end of the groove 16, while this decreases in the case of an edge according to curve 28. In contrast to Fig. 2, the supporting flank 22 of the groove 17 is also inclined here, the Angle of inclination β of the flank 22 relative to the vertical, which is indicated by the line 20 is indicated is smaller than the angle Cb. Apart from the one achieved thereby Positioning of the connecting element 18 in the flatter groove 17 by means of the inventive achieved transverse force Q, thus also a reduction in the distance between the force application point 29 on the flank 22 and the groove base 24 and thus relief of part 2 reached in the area of its smallest wall thickness.

Claims (4)

Claims: ================================ 1. Form-fitting Connection of two parts, in particular cylindrical parts, which are at least partially cover and the surfaces facing each other at least one groove each have, the groove in one part being deeper than that in the other part and in the opposing grooves of the two parts at least one common Connecting element for the transmission of perpendicular to one containing the grooves Plane-directed forces are arranged, d a -d u r c h e k e n n n z e i c h n e t that - viewed in a section across the grooves - the load on the Flank (6) of the deeper groove (4) adjacent side (8) of the connecting element (3) or the tangent on the connecting element (18) at the point of contact with the load Flan-! ke (19) of the deeper groove (16) opposite the vertical (9, 20) is inclined to the direction of force F by an angle 04, which compared to the corresponding angle ß of the load on the flank (10) of the flatter groove (5) adjacent side (11) of the connecting element (3) or the tangent at the point of contact the flank (22) of the flatter one, when the load is applied to the connecting element (18) Groove (17) is so larger that on the connecting element (3, 18) this in the shallow groove (5, 17) positioning transverse force Q acts. ¢ 2. Connection according to claim 1, characterized in that the at Load on the connecting element (3, 18) adjacent flank (6, 19) of the deeper groove (4, 16) is inclined in the contact area by the angle ob. 3. A compound according to claim 1 or 2, characterized in that the flank (10, 22) of the flatter one resting against the connecting element (3, 18) when there is a load Groove (5, 17) is inclined by the angle ß in the contact area. 4. A compound according to claim 2 or 3, characterized in that the flank (6, 19, 10, 22) resting on the connecting element (3, 18) when loaded the deeper and / or the shallower groove (4, 16, 5, 17) is straight.