Force-fitted connection of a circular metal tube in an oval housing

Abstract

A connection between a circular cylindrical tube and a plate or sleeve includes a housing extending along an axis from an inlet opening in a surface of the plate or sleeve and a circular cylindrical tube having an end fittable in the housing. The housing includes a first cylindrical truncated cone extending to the inlet opening and having a vertex angle .beta. with respect to the axis of between 5.degree. and 20.degree., and a second oval truncated cone coaxial with the first cone and connected thereto. The second cone has generatrices forming an angle .alpha. of between 0.5.degree. and 5.degree. with respect to the axis.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention relates to a connection obtained by force-fitting a circular cylindrical metal tube in a housing of oval cross-section, this housing either being the internal cavity of a sleeve or an opening in a thick plate.

2. Background of the Related Art

A similar type of connection between a circular cylindrical tube and a housing of circular section is known from French Patent Application FR-A-2 553 690. This patent application describes and claims a method of connecting a circular tube in a sleeve provided with a housing of circular cross-section and having at its inlet a double circular bevel. To ensure that the connection has high resistance to axial torsion, the bore of the sleeve has one (or more) longitudinal grooves. However, the production of these grooves or channels repesents an additional machining operation which is often awkward and, in particular, expensive.

SUMMARY OF THE INVENTION

It is therefor the object of this invention to provide a connection having a resistance to torsion equivalent to that of the above-noted French Patent Application while omitting the grooves.

The object is achieved according to the invention by producing a connection between a circular cylindrical tube and a housing in an element, such as a plate or sleeve. The connection comprises a housing in the element, the housing extending along an axis from an inlet opening in a surface of the element and comprising a first cylindrical truncated cone extending to the opening and having a vertex angle .beta. respect to the axis of between 5.degree. and 20.degree. and a second oval truncated cone coaxial with the first cone and connected thereto. The second cone has generatirces forming an angle .alpha. of between 0.5.degree. and 5.degree. with respect to the axis. A circular cylindrical tube has an end fittable into the housing.

It is preferable if the sleeve or the plate are obtained by casting which allows oval housings to be produced economically directly to the final dimensions without machining and with a surface quality which is favorable to the high mechanical strength of the connection. Chilled casting seems to be particularly suitable.

To ensure adequate gripping, it is preferable for the circumference of the oval cone at the end of the tube, once installed, to be less than the initial circumference of the cylindrical tube or than the small circumference of the optional truncated cone of the external surface of the tube.

BRIEF DESCRIPTION OF THE DRAWINGS

Various other objects, features and attendant advantages of the present invention will be more fully appreciated as the same becomes better understood from the following detailed description when considered in connection with the accompanying drawings in which like reference characters designate like or corresponding parts throughout the several views and wherein:

FIG. 1 shows an end view of a housing according to the invention as formed in a partially shown cast plate;

FIG. 2 shows an axial section along the major axis of the ellipse of the tube-plate connection produced according to the invention; and

FIG. 3 shows an axial section of the end of the tube before fitting in the housing.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The preferred embodiment of FIG. 3 shows a circular tube 1 of external diameter .phi..sub.e, having an internal diameter .phi..sub.1 and having at its one end a truncated cone-shaped surface 1a of vertical angle .gamma. and of which the minimum external diameter is .phi..sub.0 .

As seen in FIGS. 1 and 2, this tube is connected to a plate 2 having a housing 3 extending from an inlet opening thereof and formed as a first circular truncated cone 2a (in the region a) of which vertex angle is .beta. and of which the opening diameter is .phi..sub.A. Cone 2a is connected to a second truncated oval cone 2b (in the region b) of which the directrix is an oval B and of which the generatrices B-D form an angle .alpha. with the central housing axis 4. The circumference of the oval cone 2b at a position to which the end of the installed tube 1 extends is preferably less than (.pi...phi..sub.0), or (.pi...phi..sub.e) if the tube is not bevelled.

Angle .gamma. is equal to or greater than angle .beta.. Diameter .phi..sub.0 is less than diameter .phi..sub.A.

EXAMPLE 1

Fittings such as those shown in FIGS. 1, 2 and 3 were produced from:

1. A circular tube of external diameter .phi..sub.o =28.2 mm, having a thickness of 1.6 mm and an end bevel .phi..sub.o =23.4 mm with an angle .gamma.=11.degree., the tube being composed of Al alloy 5086 in state H16 according to the Aluminum Association designations.

2. Sleeves composed of Al alloy A-S 7 G.0.6, chill molded in state Y33 and having four housings of differing geometry and surface state (Table 1). In all cases, the inlet bevel 2a was machined by precision turning to an opening .phi..sub.A =28.6 mm, an angle .beta.=11.degree. and an axial length A-B of about 6 mm. The oval cone portion 2b of each of the four housings had the following characteristics:

TABLE 1______________________________________ Dimensions at 20 mm fromHousing the inlet andNumber Geometry State (A) (mm) .alpha. (degrees)______________________________________ Axes:1 Elliptical Cone As cast major = 1 23.4 mm minor = 22.9 mm2 Circular Cone As cast diameter = 1 23.15 mm3 Circular Cone Precision diameter = 1 machined 23.15 mm4 Circular Precision diameter = 0 Cylinder machined 23.15 mm______________________________________

The axial length of fitting was lo=35 mm in all cases.

The average and the standard deviation (.sigma.) in the axial fitting force, the axial wrenching force and axial torsion stress were measured on the connections thus produced, with five fittings in each of the above cases.

The results are compiled in the Table II below. It can be seen that the oval geometry provides an appreciable gain in torsional resistance over the circular geometry, whereas the as-cast surface state increases the axial extraction force over the precision machined state.

Finally, not only does the conical geometry increases the fitting force, it also contributes a substantial gain in axial extraction force relative to the cylindrical geometry.

Obviously, numerous modifications and variations of the present invention are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the invention may be practiced otherwise than as specifically described herein.

TABLE II__________________________________________________________________________Designation Connecting force Extraction face Torsional momentof type of Definition in Newtons E in Newtons C in Newton-metersconnection of housing .sup.--A .sup..sigma. A .sup.--E .sup..sigma. E .sup.--C .sup..sigma. C__________________________________________________________________________1 Oval conical as cast 24 800 1 050 19 050 1 300 .gtoreq.320.sup.(a) --2 Round conical as cast 25 050 1 060 19 100 1 300 230 273 Round conical machined 24 450 5 350 14 700 2 550 180 554 Round cylindrical machined 20 050 5 320 10 550 650 165 52__________________________________________________________________________ Influence on the characteristics TorsionalConnections Connecting force A Extraction force E moment Ccompared Parameters .sup.--A .sup..sigma. A .sup.--E .sup..sigma. E .sup.--C .sup..sigma. c__________________________________________________________________________1 compared to 2 Oval/round .perspectiveto. .perspectiveto. .perspectiveto. .perspectiveto. >40% --2 compared to 3 Crude/machined .perspectiveto. .times. 1/5 +30% .times. 1/2 +30% .times. 1/23 compared to 4 Conical/cylindrical +20% .perspectiveto. +40% .perspectiveto. +10% .perspectiveto.__________________________________________________________________________ .sup.(a) deformation of the tube, connection intact

Claims

1. A connection between a circular cylindrical tube and an element having a housing, comprising:

an element defining a housing extending along an axis from an inlet opening in a surface of said element, said housing comprising:

(a) a first cylindrical truncated conical bore in said housing and extending to said opening and having a vertex angle with respect to said axis of between 5.degree. and 20.degree.; and

(b) a second oval truncated conical bore in said housing and coaxial with said first conical bore and contiguous therewith, said second conical bore having generatrices forming an angle of between 0.degree. and 5.degree. with respect to said axis; and

a circular cylindrical tube having an end fitted in said housing.

2. The connection of claim 1, wherein said tube, prior to fitting in said housing, has at said end a circular truncated conical external surface whose vertex angle .gamma..gtoreq..beta., wherein a minimum diameter .phi..sub.o of said external surface is smaller than a diameter .phi..sub.A of said inlet opening.

3. The connection of claim 1, wherein walls of said housing at said second conical bore are unmachined.

4. The connection of claim 2, wherein walls of said housing at said second conical bore are unmachined.

5. The connection of claim 2, wherein said tube is fitted in said housing and a diameter of said second conical bore at a position corresponding to said end of said tube is less than .pi...mu..sub.o.