Hinge for vehicle doors

Abstract

 Hinge for a vehicle door, comprising:

• a first hinge part (112) and a second hinge part (114) that can rotate relative to each other about a hinge axis (122),
• a hinge pin (116) mounted in the first hinge part (112) so that it can rotate about the hinge axis (122) and is constrained permanently by the first hinge part (112) in the direction of its own axis (122), and
• a screw (134) arranged parallel to the hinge axis (122) for fixing the second hinge part (114) detachably to the pin (116).

The hinge includes a centring part (150) that is independent of the screw (134) and that has a first centring surface (158) and, coaxial with this, a second centring surface (160). The first centring surface (158) sits in a corresponding centring seat (162) formed in the second hinge part (114) and coaxial with the hinge axis (122), and the second centring surface (160) is intended to fit into a reference surface (146) in a gripper (142).

Description

[0001] The present invention relates to a hinge for a vehicle door and is of the type that comprises a first hinge part and a second hinge part connected together by a hinge pin that can rotate relative to the first hinge part and is disengageably to the second hinge part by a screw that extends parallel to the hinge axis.

[0002] Figure 1 of the attached drawings illustrates a hinge according to the prior art. In Figure 1 the first and second hinge parts are labelled 12 and 14, respectively. A hinge pin 16 has a cylindrical shank 18 able to rotate inside a hole 20 formed in the first hinge part 12. A bush 19 is inserted between the pin 16 and the hole 20 and its ends are bent out against both transverse ends of the first hinge part 12. The axis of rotation of the pin 16 defines a hinge axis 22. The pin 16 includes a frustoconical portion 24 from which a second cylindrical portion 26 containing a tapped hole 28 projects.

[0003] The pin 16 is fixed permanently to the first hinge part 12, such that it cannot move in the direction of the hinge axis 22, by upsetting an end portion 30 after insertion of the cylindrical shank 18 into the hole 20. The upset portion 30 grips a washer 31. In the upset portion 30 of the pin 16 is a centring hole 32 which is coaxial with the hinge axis 22.

[0004] The second hinge part 14 is secured detachably to the pin 16 by a screw 34 engaged in the tapped hole 28. The second hinge part 14 contains a frustoconical seat 36 which fits against the frustoconical portion 24 of the pin 16. The screw 34 includes a frustoconical centring portion 38.

[0005] The hinge 10 is mounted automatically on a vehicle using a numerical-control manipulator equipped with two opposed grippers 40, 42 which grasp the hinge 10 in the direction of the hinge axis 22. The grippers 40, 42 each have their own centring surfaces 44, 46 that engage with the centring hole 32 and with the centring surface 38. The grippers 40, 42 are aligned with a reference axis of the automatic manipulating device. In order that the mounting of the hinge 10 can be performed as accurately as possible, it is desirable to have the hinge axis 22 aligned as accurately as possible with the reference axis of the manipulating device. Consequently, in order to improve the accuracy with which the hinge 10 is mounted, the error of concentricity between the centring hole 32 and the centring surface 38 must be maintained within the lowest possible values.

[0006] In the known system described above the total error of concentricity Et between the centring surfaces 32 and 38 is given by the sum of four partial errors of concentricity termed E1, E2, E3 and E4:

E1: error of concentricity between the hole 32 and the hinge axis 22 ≅ 0.1

E2: error of concentricity between the frustoconical surface 24 and the hinge axis 22 ≅ 0.05

E3: error of concentricity between the tapped hole 28 and the hinge axis 22 ≅ 0.3

E4: error of concentricity between the reference surface 38 and the threaded portion of the screw 34 ≅ 0.3.

Et: total error of concentricity between the centring hole 32 and the centring surface 38 ≅ 0.75.

[0007] The values indicated for the errors of concentricity are those obtained by normal mechanical working of the components in question.

[0008] The object of the present invention is to provide a hinge for a vehicle door of the type described earlier that has a total error of concentricity less than that of the known version.

[0009] According to the present invention this object is achieved with a hinge having the features forming the subject of the main claim.

[0010] The features and advantages of the hinge according to the present invention will be described below with reference to the enclosed drawings, in which:

• Figure 1, which has already been described above, is a diagrammatic axial section through a hinge in accordance with the prior art, and
• Figure 2 is a diagrammatic axial section through a hinge in accordance with the present invention.

[0011] In Figure 2, parts corresponding to those previously described are indicated by the same numerical references increased by 100. As in the case of the known hinge described above, the hinge of the present invention comprises a first hinge part 112 and a second hinge part 114. These are connected together by a hinge pin 116 that can rotate relative to the first hinge part 112 about the hinge axis 122.

[0012] The hinge 110 according to the present invention differs from the known hinge essentially in that it includes a centring part 150 that is not constrained by the screw 134. The centring part 150 has a hole 152 through which the shank of the screw 134 extends with play. The centring part 150 is positioned around the screw 134 before the threaded portion 154 is formed by conventional rolling. As is known, thread forming by rolling produces an increase in diameter and therefore, after the threaded portion 154 has been formed, the centring part 150 is held in place between the threaded portion 154 and the head 156 of the screw 134.

[0013] The centring part 150 has two coaxial frustoconical centring surfaces, one at either end, marked 158 and 160, respectively. The surface 158 sits in a centring seat 162 formed on the second hinge part 114 and coaxial with the hinge axis 122. The centring surface 160 meanwhile is intended to fit into the reference surface 146 of the gripper 142. The screw 134 pushes the centring part against the centring seat 162 of the second hinge part 114. The centring part 150 therefore assumes a position with respect to the hinge axis 122 that is independent of the error of concentricity of the tapped hole 128 and of the threaded portion 154.

[0014] In the solution according to the present invention the total error of concentricity between the centring hole 132 and the centring surface 160 is given by the sum of the following elements:

E1: error of concentricity between the hole 132 and the hinge axis 122 ≅ 0.1

E2: error of concentricity between the frustoconical surface 124 and the hinge axis 122 ≅ 0.05

E3: error of concentricity between the frustoconical surface 136 and centring seat 162 of the second hinge part 114 ≅ 0.1

E4: error of concentricity between the frustoconical surfaces 158, 160 of the centring part 150 ≅ 0.1

Et: total error of concentricity between the centring hole 132 and the centring surface 160 ≅ 0.35.

[0015] The present invention thus provides a reduction of more than 50% in the error of concentricity between the reference surfaces of the hinge for very little increase in cost due to the presence of the centring part 150.

Claims

1. Hinge for a vehicle door, comprising:

- a first hinge part (112) and a second hinge part (114) that can rotate relative to each other about a hinge axis (122),

- a hinge pin (116) mounted in the first hinge part (112) so that it can rotate about the hinge axis (122) and is constrained permanently by the first hinge part (112) in the direction of its own axis (122), and

- a screw (134) arranged parallel to the hinge axis (122) for fixing the second hinge part (114) detachably to the pin (116),

   the said hinge being characterized in that it includes a centring part (150) that is independent of the screw (134) and that has a first centring surface (158) and, coaxial with this, a second centring surface (160), in which the first centring surface (158) sits in a corresponding centring seat (162) formed in the second hinge part (114) and coaxial with the hinge axis (122), and in which the second centring surface (160) is intended to fit into a reference surface (146) in a gripper (142).

2. Hinge according to Claim 1, characterized in that the abovementioned centring part is mounted with clearance on the shank of the abovementioned screw (134) and is held on the screw (134) between the threaded portion (154) and the head (156).

3. Hinge according to Claim 1, characterized in that the abovementioned centring part (150) has two frustoconical surfaces (158, 160), one on either end, forming the abovementioned centring surfaces.

4. Hinge according to Claim 1, characterized in that the second hinge part (114) has, coaxial with the hinge axis (122), a frustoconical centring surface (162) against which one centring surface (158) of the centring part (150) is pushed by the tension of the screw (134).

Drawing