A method of closing an end of a metal pipe

Abstract

 A method of closing an end of a metal pipe comprises the step of applying a substantially radial force to the outer surface of the pipe (10) in the vicinity of the end (12) to be closed. The zone of application of the force is moved continuously both circumferentially and radially relative to the pipe (10) so as to bring about a progressive inward deformation of the lateral wall of the pipe (10) until the end (12) is completely closed.

Description

[0001] The present invention relates to a method of closing an end of a metal pipe in a fluid-tight manner.

[0002] The method according to the invention is used, in particular, in the field of the production of heat exchangers for vehicles and, more precisely, for the manufacture of a condenser distributor which is generally made from an extruded or drawn pipe of which one or both ends have to be closed in a fluid-tight manner, possibly after the insertion partitions for distributing the flow. However, the present invention is not limited to this specific field and may be used wherever it is necessary to form a fluid-tight closure at an end of a metal pipe.

[0003] When the ends of pipes made of copper and/or aluminium or of another metallic material have to be closed in a fluid-tight manner in applications in which the sealing region has to withstand high pressures and temperatures, a welded cover is generally used. The welding operation involves difficulties in the automation of the production process, often requires re-welding and finishing operations, and generally involves a fairly significant cost.

[0004] The object of the present invention is to provide a system for the closure of the ends of pipes which produces a fluid-tight closure without welding, the closure being formed at a minimal cost and having good resistance to high pressures.

[0005] According to the present invention, this object is achieved by a method having the characteristics forming the subject of the claims.

[0006] Further characteristics and advantages of the present invention will become clear in the course of the following detailed description, given purely by way of non-limiting example, with reference to the appended drawings in which Figures 1 and 2 are schematic side views showing two steps of the method of the invention.

[0007] In Figure 1 a metal pipe, indicated 10, has an end 12 which is to be sealed by the method of the invention.

[0008] The tools required to close the end 12 comprise a tubular support 14 in which the pipe 10 is positioned. The support 14 is constituted, for example, by a resilient bush for insertion in a chuck 16 rotatable about an axis 18 coinciding with the longitudinal axis of the pipe 10. The support 14 has the main purpose of preventing damage to the external surface of the pipe 10 when it is gripped by the chuck 16. The support 14 has a flat surface 20 from which a portion A of the pipe 10 projects.

[0009] In order for the method of the invention to give good results, the dimension A must be determined with care. In fact, if the dimension A is too small in comparison with the diameter D of the pipe 10 it is not possible to close the end whereas, if the dimension A is too large, excessive back-flow and deformation of the material are produced. Experience has shown that the relationship between the dimension A and the diameter should be substantially in accordance with the following equation:

in which:

A is the measurement in mm of the portion of the pipe projecting axially from the surface 20 of the support 14,

D is the diameter of the pipe 10 in mm,

K is a constant, the value of which may vary from 1.5 to 2.5, and

b is a factor the magnitude of which may vary between 0.15 and 0.25.

[0010] For example, it has been found experimentally that good results are achieved with the relationship:

[0011] The rate of rotation of the pipe 10 about its axis during the operation to close the end 12 may vary from 600 to 1000 revolutions/minute. A normal value of the rate of rotation of the chuck 16 which achieves good results is about 800 revolutions/minute.

[0012] The tools for closing the end of the pipe 10 also comprise a wheel 22 fixed idly to a tool-holder 24. The wheel 22 can rotate freely about an axis 26 parallel or substantially parallel to the axis 18 of the pipe 10. The tool-holder 24 can move along a straight line perpendicular to the axis 18 of the pipe 10 and indicated by the arrow 28 in Figure 1.

[0013] The wheel 22 has a flat surface 30 which is substantially aligned with the flat surface 20 of the support 14. In order to achieve a good qualitative result and to avoid trimming and deburring of material during the closure operation, the distance between the surfaces 30 and 20 in a direction parallel to the axis 18 must be close to zero.

[0014] The surface of the wheel 22 which is intended to contact the wall of the pipe 10 has a curvature 32 having a radius R which is preferably equal to or greater than the dimension A by which the end to be closed projects.

[0015] The idle wheel 22 represents the most appropriate tool for implementing the method according to the invention. However, the method could also be implemented with tools of different kinds. For example, a non-rotatable metal body having a profile similar to that of the cross-section of the wheel 22 could be used instead of the wheel 22. The idle wheel 22 has the advantage of reducing the contact friction and the heat which are generated during the deformation step of the pipe 10 and achieves a better result from the aesthetic point of view. However, by forgoing some of these advantages, it is possible to implement the method of the invention with non-rotatable tools.

[0016] Starting from the configuration shown in Figure 1, the method according to the invention is implemented simply by the rotation of the pipe 10 and the movement of the tool-holder 24 towards the axis of 18 of the pipe 10 in the direction of the arrow 28. The forward movement of the tool-holder 24 is stopped when the junction between the arcuate surface 32 and the flat surface 30 is a little beyond the axis 18.

[0017] Figure 2 shows the configuration of the tools and of the pipe 10 upon completion of the forward stroke of the tool-holder 24. It can be noted that the projecting portion of the pipe 10 has been completely flattened and turned over inwardly. The upsetting of the material and the heat of friction generated during the process bring about plastic deformation of the material which completely seals the end. During the forward stroke of the tool-holder 24, the wheel 22 applies to the wall of the pipe 10 an inward deformation force the point of application of which varies continuously both circumferentially, as a result of the rotation of the pipe 10, and radially, as a result of the advance of the tool-holder 24. The effect of the inward deformation is to reduce the width of the hole progressively until it is completely closed.

[0018] The closure produced requires no re-welding operations since it seals itself as a result of the heat of friction produced. The closure is particularly resistant to high working pressures. The method of the invention can easily be automated and, in comparison with a conventional welding method, is very easy to implement and has a minimal cost.

Claims

1. A method of closing an end of a metal pipe (10), characterized in that it comprises the step of applying a substantially radial force to the external surface of the pipe (10) in the vicinity of the end (12) to be closed, the zone of application of the force being moved continuously both circumferentially and radially relative to the pipe (10), so as to bring about a progressive inward deformation of the lateral wall of the pipe (10) until the end (12) is completely closed.

2. A method according to Claim 1, characterized in that the force is applied by means of a wheel (22) rotatable freely about an axis (26) substantially parallel to the axis (18) of the pipe (10).

3. A method according to Claim 2, characterized in that the wheel (22) and the pipe (10) can move relative to one another along a line substantially perpendicular to the axis (18) of the pipe (10) in order to move the zone of application of the force radially.

4. A method according to Claim 1, characterized in that, during the application of the radial force, the pipe (10) is rotated about its own longitudinal axis (18) in order to vary the position of the zone of application of the force circumferentially.

5. A method according to Claim 2, characterized in that the pipe (10) is held by a support (14) from which the end (12) to be closed projects by a predetermined amount (A).

6. A method according to Claim 5, characterized in that the wheel (22) has a contact surface (32) having a radius of curvature (R) of a length equal to or greater than the axial length (A) of the portion of the pipe (10) which projects from the support (14).

7. A method according to Claim 5, characterized in that the wheel (22) has a flat surface (30) which, during the forward movement towards the axis(18) of the pipe (10) remains substantially aligned with a flat surface (20) of the support (14) from which the end (12) to be closed projects.

8. A method according to Claim 5, characterized in that the relationship between the portion of the pipe (10) which projects from the support (14) and the diameter (D) of the pipe (10) is substantially in accordance with the following equation:

in which:

A is the measurement in mm of the portion of pipe (10) projecting from the support (14),

D is the diameter of the pipe (10) in mm,

K is a constant variable from 1.5 to 2.5, and

b is a factor variable from 0.15 to 0.25.

Drawing