WO2004099632A1

WO2004099632A1 - Arrangement made of a plastic part and a metal insert with a captive screw

Info

Publication number: WO2004099632A1
Application number: PCT/EP2004/050541
Authority: WO
Inventors: Werner Schnabel
Original assignee: Siemens Aktiengesellschaft
Priority date: 2003-05-05
Filing date: 2004-04-16
Publication date: 2004-11-18
Also published as: DE10319978A1; DE10319978B4

Abstract

An arrangement made of a plastic part (1) and a metal insert (8) with a captive screw (4), wherein the metal insert (8) can be introduced into a fixing hole (3) of the plastic part (1) in order to define fixing forces transmitted to the plastic part (1) when the plastic part (1) is screwed to another component (2). The continuous hole of the metal insert (8) has an oval cross-diameter, whereby the largest diametrical dimension is located in the longitudinal direction (L) of the plastic part, in order to compensate tolerances in a longitudinal direction. The continuous hole (9) of the metal insert (8) is provided with two opposite projections (10) in the form of acclivities which keep the fixing screw (4) captive in the plastic part (1) during mounting.

Description

description

Arrangement of plastic part and metallic insert with captive screw

The present invention relates to an arrangement of a plastic part and a metallic insert according to the preamble of claim 1 and a plastic part according to the preamble of claim 7.

The attachment of a plastic part to another component such as Fastening an intake manifold to the cylinder head of an internal combustion engine by means of fastening screws is problematic in that the fastening forces (tensioning forces) transferred from the fastening screws to the plastic part can lead to deformation and flow of the plastic. Metallic inserts (torque limiters) are therefore often inserted into the mounting holes in order to limit the mounting forces transferred to the plastic part.

In the case of the screw connection between the intake manifold and the cylinder head of an internal combustion engine, a plurality of fastening holes with metallic inserts for a corresponding number of fastening screws are generally provided in the longitudinal direction of the intake manifold flange. The mounting holes can have different distances from one another due to the inevitable tolerances during injection molding of the plastic part, wherein the tolerances can add up to, for example, 1.5 mm. In order to be able to screw the plastic part to the other part despite the unchanged dimensions of the fastening holes, the screw shaft of the fastening screws had to be made correspondingly thin, but this is not possible for reasons of strength. On the other hand, one could think of making the fastening holes of the plastic part and the metal inserts arranged in them so large in diameter that they allow the tolerances to be compensated. In this case, however, the fastening screws would be so loose in the metal inserts that they would not be held captive in them.

However, for handling reasons it is often desirable to pre-assemble the plastic part, the metallic inserts and the fastening screws and then to keep the fastening screws captive in the metallic inserts. However, this is not possible with conventional metallic inserts for the reasons described.

The present invention is based on the object of an arrangement comprising a plastic part and a fastening screw according to the preamble of claim 1

Develop plastic part according to the preamble of claim 7 so that the fastening screw for the purpose of pre-assembly in the metallic insert or plastic part is held captive and can still be easily screwed into the other component without a reduction in cross-section of the fastening screw being necessary.

According to the invention, this object is achieved by the invention defined in claims 1 and 7.

According to the solution of the invention, the through hole of the metallic insert has a non-circular cross section, the largest diametrical dimension of which is in the longitudinal direction of the plastic part and the smallest diametrical dimension of which is designed for tight guidance of the fastening screw in the through hole. Furthermore, at least one projection is provided on the wall of the through hole of the metallic insert, which protrudes transversely to the longitudinal direction and thus transversely to the largest diametrical dimension of the through hole into the interior of the through hole in order to hold the fastening screw captively in the through hole. This geometrical design of the metallic insert allows tolerances in the direction in which the greatest tolerances occur to be compensated for, without this requiring a reduction in the shank cross section of the fastening screw. A conventional fastening screw with customary dimensions can therefore be used. Since the fastening screw is also closely guided transversely to the direction in which the greatest tolerances occur and at least one projection is provided in this direction, the

Fastening screw held captive in the through hole of the metallic insert. The plastic part, the metal insert and the fastening screw can therefore be preassembled and connected to the other component as a preassembled unit.

Appropriately, two diametrically opposite projections in the form of ramps are provided on the wall of the through hole of the metallic insert, which come into engagement with the thread of the fastening screw when the fastening screw is moved through the metallic insert. The fastening screw is thus inserted into the metal insert for pre-assembly by turning.

The cross-section of the through hole of the metallic insert is preferably oval or other elongated, e.g. an approximately rectangular shape. The metallic insert with its projections can be produced, for example, by sintering or extrusion, or also by rolling and looking up.

In a further embodiment of the invention, it is provided that the projection or the projections of the metallic insert are arranged at an axial end of the through hole in order to be able to pull the fastening screw back into the interior of the through hole before screwing the plastic part to the other component. This makes it possible lent, the preassembled unit made of plastic part, metallic insert and fastening screws on the other component without problems to screw it with this.

In order to prevent the fastening screw and the metallic insert from being pushed out of the fastening hole of the plastic part during this assembly step, if the fastening screw with its threaded section still protrudes from the metallic insert, the metallic insert is preferably provided with a shoulder on its circumference , which cooperates with a corresponding counter shoulder in the fastening hole of the plastic part in order to axially secure the metallic insert in the plastic part. This also ensures that the metallic insert is inserted in the correct orientation in the fastening hole of the plastic part.

The solution according to the invention can also be used with a plastic part which is screwed to the other component without using metallic inserts. In this case, the geometry of the through hole of the metallic insert provided according to the invention is provided directly on the fastening hole of the plastic part. This means that the fastening hole of the plastic part has a non-circular cross-section, the largest diametrical dimension of which is in the longitudinal direction of the plastic part and the smallest diametrical dimension of which is designed for tight guidance of the fastening screw, and that at least one projection is provided on the wall of the through hole of the plastic part is, which projects transversely to the longitudinal direction into the interior of the mounting hole in order to hold the mounting screw captive in the plastic part.

In this case, since the fastening screw can only be tightened with a lower pretensioning force and, in addition, the plastic of the plastic part settles over time, the fastening screw can loosen gradually. purpose It is therefore moderately provided that the thread of the fastening screw in the other component is secured by an adhesive connection, as is basically known in the prior art.

An embodiment of the invention is explained in more detail with reference to the drawing. It shows:

1 shows a section through an arrangement of plastic part, metallic insert and fastening screw designed according to the invention, which is connected to another component;

FIG. 2 shows a section rotated through 90 ° of the arrangement shown in FIG. 1;

Fig. 3 is a plan view of the metallic insert of the arrangement in Figs. 1 and 2.

As in Figs. 1 and 2, a plastic part 1 is fastened to another component 2 by a screw connection. The plastic part 1 can be, for example, the flange of an intake manifold of an internal combustion engine, while the other component 2 is a cylinder head of the internal combustion engine. It goes without saying that in such an application a plurality of such screw connections are provided at a distance from one another in a longitudinal direction L (see the double arrow in FIG. 2), but only one such screw connection is shown for the sake of simplicity. Otherwise, other applications are also conceivable in which a plastic part is fastened to another component by means of several screw connections.

As shown, the plastic part 1 has a continuous fastening hole 3, through which a fastening screw 4 extends and is screwed to a threaded bore of the other component 2 aligned with the fastening hole 3. The fastening screw 4 is a conventional Before expansion screw with a head 5, a screw shaft 6 and a threaded section 7. The diameter of the threaded shaft 6 corresponds to the basic diameter of the thread of the threaded section 7.

In the mounting hole 3 of the plastic part 1, a metallic insert 8 is inserted in the form of a sleeve, the axial length of which essentially corresponds to the length of the mounting hole 3. The metallic insert 8 thus acts as a "torque limiter", which limits the clamping forces transmitted to the plastic part 1 when the plastic part 1 is screwed to the other component 2.

As already mentioned, several screw connections are provided in the longitudinal direction L of the plastic part 1 (intake manifold flange). When manufacturing the plastic part 1, for example during injection molding, it is inevitable that the fastening holes 3 for these screw connections have different distances from one another due to manufacturing tolerances or other tolerances. There is then a center offset between the center lines of the fastening holes of the plastic part 1 on the one hand and the threaded bores of the other component 2 on the other. As mentioned at the beginning, the tolerances can add up to 1.5 mm, for example.

In order to make it possible to compensate for such tolerances, the through hole 9 of the metallic insert 8 has an oval shape, as can be seen from FIG. 3. Instead of an oval shape, another elongated shape, such as an approximately rectangular shape, could also be used. In any case, the largest diametrical dimension of the through hole 9 of the metallic insert 8 lies in the longitudinal direction L, in which the greatest tolerances occur. As shown in FIG. 2, the threaded shaft 6 of the fastening screw 4 then has a relatively large play S in relation to the metallic insert 8 in the longitudinal direction L. The metallic insert 8 expediently has a uniform wall thickness, so that the circumference of the metallic insert 8 has the same elongated shape in cross section as the through hole 9. The metallic insert 8 thus has an oval or elongated cross section, to which the cross section of the fastening hole 3 of the plastic part 1 is expediently adapted.

The through hole 9 of the metallic insert 8 has a diametrical dimension in a direction transverse to the longitudinal direction L, which ensures tight guidance of the fastening screw 4 in the metallic insert 8. Furthermore, two diametrically opposite projections 10 in the form of ramps are provided on the wall of the through hole 9 of the metallic insert 8, which ramps cross the longitudinal direction L into the interior of the

Project through hole 9, as in Figs. 1 and 3 can be seen. The projections 3 are designed and dimensioned such that they engage the thread of the fastening screw 4 when the fastening screw 4 is moved axially through the metallic insert 8. To be more precise, the thread of the fastening screw 4 is screwed through the projections 10 so that the screw 4 is introduced into the metallic insert 8 by turning, similarly to a threaded connection.

The oval or elongated shape of the metallic insert 8 and thus the through-hole 9 allows a compensation of tolerances of the fastening hole 3 in the longitudinal direction L. The two projections 10 and the tight guidance of the fastening screw 4 in a direction transverse to the longitudinal direction L ensure a captive mounting of the fastening screw 4 in the metallic insert 8 before fastening the plastic part 1 to the other component 2.

The two projections 10 are provided on the (in FIG. 1) upper axial end of the metallic insert 8 in order to insert the threaded section 7 into the through hole 9 of the metallic one To be able to move in, as will be explained in more detail.

At the same axial end, the metallic insert 8 is provided on its circumference with an undercut in the form of a shoulder 11, which interacts with a counter shoulder 12 of an annular projection in the fastening hole 3 of the plastic part 1, as will also be explained in more detail.

The assembly of the plastic part 1 (flange of an intake manifold) on the other component 2 (cylinder head) will now be described. In this case, a screw connection (not shown) is used in a central region of the suction pipe, in which the metallic insert 8 and thus the fastening hole 3 of the plastic part are circular-cylindrical, as a result of which the plastic part 1 is centered relative to the other component 2. Outside of this centering screw connection, screw connections are then used, as shown in the drawing.

In order to attach the plastic part 1 to the other component 2, the component 1, the metallic inserts 8 and the fastening screws 4 are preassembled in order to form a unit to be handled separately. For this purpose, the metallic inserts 8 are first inserted from below (in FIGS. 1 and 2) into the associated fastening holes 3 in the plastic part 1. The shoulder 11 provided on the respective metallic insert 8 ensures that the insert 8 is inserted in the correct orientation in the associated fastening hole 3, so that the two projections 10 come to rest on the axial end of the through hole 3 facing away from the component 2. By interacting the paragraph 11 of the insert 8 with the counter shoulder 12 in the mounting hole 3, the axial position of the insert 8 is secured in the rest.

Then the fastening screws 4 by screwing their thread into the projections 10 in the associated metal Lischen inserts 8 moved axially into it. The fastening screws 4 are then held captive by the projections 10 in the associated metallic inserts 8 and thus in the plastic part 1. The plastic part 1 with the metallic inserts 8 and the fastening screws 4 thus form a preassembled unit.

Since the projections 10 are provided at the (in FIGS. 1 and 2) upper end of the associated metallic insert 8, the threaded section 7 of the fastening screws 4 can in each case be completely drawn into the through hole 9 of the associated metallic insert 8. The pre-assembled unit made of plastic part 1, inserts 8 and fastening screws 4 is then placed on the top of the other component 2. Should one or more of the fastening screws 4 protrude with their threaded section 7 from their associated metallic insert 8, the shoulder 11 of the relevant metallic insert 8 in cooperation with the counter shoulder 12 prevents the fastening screw 4 from protruding together with the metallic insert 8 the mounting hole 3 is pushed out.

When the plastic part 1 with the metallic inserts 8 and the fastening screws 4 is placed on the other component 2, the fastening screw of the centering screw connection (not shown) arranged in a central area is first tightened. Then the other fastening screws 4 are tightened. The clearance S caused by the elongated shape of the metallic insert 8 enables tolerances or a center offset of the fastening holes 3 to be compensated for in relation to the threaded bores of the other component 2 in the longitudinal direction L, so that the fastening screws 4 can be easily inserted into the associated threaded bores of the other component 2 can be screwed.

Claims

claims

1. Arrangement of a plastic part (1) and a metallic insert (8) which is inserted into a fastening hole (3) of the plastic part (1) and is designed as a sleeve with a through hole (9) through which a fastening screw ( 4) can be plugged through in order to screw the plastic part (1) to another component (2), the plastic part (1) having a longitudinal direction (L) in which, in addition to the fastening hole (3), there are further fastening holes which are from the mounting hole (3) may have different distances due to tolerances, characterized in that the through hole (9) of the metallic insert (8) has a non-circular cross-section, the largest diametrical dimension of which is in the longitudinal direction (L) of the plastic part (1) and its smallest diametrical dimension is designed for a tight guidance of the fastening screw (4), and that on the wall of the through hole (9) of the metallic insert (8) m at least a protrusion (10) is provided which is transverse to the

Longitudinal direction (L) protrudes into the interior of the through hole (9) in order to keep the fastening screw (4) in the plastic part (1) captive.

2. Arrangement according to claim 1, so that two diametrically opposite projections (10) are provided on the wall of the through hole (9) of the metallic insert (8).

3. Arrangement according to claim 1, characterized in that the projection or the projections (10) each have the shape of a ramp which engages with the thread of the fastening screw (4) when the fastening screw (4) through the metallic insert (8) is moved through.

4. Arrangement according to one of the preceding claims, characterized in that the cross-section of the through hole (9) of the metallic insert (8) has an oval or other elongated shape.

5. Arrangement according to one of the preceding claims, characterized in that the projection or the projections (10) of the metallic insert (8) are arranged at an axial end of the through hole (9) to the fastening screw (4) before screwing the To be able to withdraw the plastic part (1) with the other component (2) into the interior of the through hole (9).

6. Arrangement according to one of the preceding claims, characterized in that the metallic insert (8) on its circumference has a shoulder (11) which cooperates with a corresponding counter shoulder (12) in the fastening hole (3) of the plastic part (1) to axially secure the metallic insert (8) in the plastic part (1).

7. Plastic part with a fastening hole through which a fastening screw can be inserted in order to connect the plastic part to another component, the plastic part having a longitudinal direction in which, in addition to the fastening hole, there are further fastening holes which are different from the

Fastening hole may have different distances due to tolerances, characterized in that the fastening hole of the plastic part has a non-circular cross-section, the largest diametric dimension of which is in the longitudinal direction of the plastic part and the smallest diametric dimension of which is designed for tight guidance of the fastening screw and that on the wall of the Fastening hole of the plastic part is provided at least one projection which projects transversely to the longitudinal direction into the interior of the fastening hole in order to hold the fastening screw captively in the plastic part.

8. Plastic part according to claim 7, so that two diametrically opposite projections are provided on the wall of the fastening hole of the plastic part.

9. Plastic part according to claim 7 or 8, so that the projection or the projections each have the shape of a ramp, which come into engagement with the thread of the fastening screw when the fastening screw is moved through the fastening hole of the plastic part.

10. Plastic part according to one of claims 7 to 9, so that the cross-section of the fastening hole of the plastic part has an oval or other elongated shape.

11. Plastic part according to one of claims 7 to 10, characterized in that the projection or the projections are arranged at an axial end of the fastening hole of the plastic part in order to retract the fastening screw before screwing the plastic part to the other component inside the fastening hole can.

12. Plastic part according to one of claims 7 to 11, so that the thread of the fastening screw in the other component is secured by an adhesive connection in the completely assembled state.