阅读说明：本技术 用于制造具有齿排的调节机动车座椅用的构件的方法 (Method for producing a component for adjusting a motor vehicle seat having a row of teeth ) 是由 H.苏莱曼 H-W.德特默 M.申克 J.维特 于 2019-07-05 设计创作，主要内容包括：本发明涉及一种用于制造具有齿排的调节机动车座椅用的构件的方法。本发明的目的是提供一种方法,利用其来消除现有技术的缺点。该目的由此来实现,即齿排(2)被预切削到粗轮廓上且接下来被加热且在该状态中在压模中被带到最终轮廓上,或者构件(1)的在其中应构造齿排的区域(1.2)被加热且接下来在该状态中在冲模中被最终切削。(The invention relates to a method for producing a component for adjusting a motor vehicle seat, comprising a row of teeth. It is an object of the present invention to provide a method with which the disadvantages of the prior art are eliminated. The aim is achieved in that the tooth rows (2) are pre-cut onto the rough contour and then heated and brought in this state in a die onto the final contour, or in that the regions (1.2) of the component (1) in which the tooth rows are to be formed are heated and then in this state are finally cut in a die.)

1. A method for producing a component for adjusting a motor vehicle seat having rows of teeth, characterized in that the rows of teeth (2) are pre-cut to a rough contour and then heated and brought in this state to a final contour in a die (4), or in that a region (1.2) of the component (1) in which the rows of teeth (2) are to be formed is heated and then finally cut in a die (7) in this state.

2. The method of claim 1, wherein the component is manufactured from coils in a sequential composite process.

3. Method according to claim 1 or 2, characterized in that the heating is effected inductively.

4. Method according to any one of the preceding claims, characterized in that the component (1) is cooled in a plurality of stages after the tooth row (2) is built to the final profile.

Technical Field

The invention relates to a method for producing a component for adjusting a motor vehicle seat, comprising a row of teeth (Zahnreihe).

Background

Such components are precision components which are produced by precision cutting and subsequent hardening by means of heat treatment. The disadvantage of this current production method is, in particular, that large inherent stresses are produced in the finished product by the forming process, which lead to uncontrolled dimensional deviations of the component after the heat treatment. Furthermore, since these two severely separated manufacturing processes-precision cutting and heat treatment-require increased logistics costs, they result in higher overall manufacturing costs. Furthermore, the stamping shrinkage (Stanzeinzug) occurring during the production is disadvantageous, which leads to a loss of the bearing capacity.

Disclosure of Invention

The object of the present invention is to provide a method with which these disadvantages are eliminated.

This object is achieved according to the invention with a method having the features of claim 1.

The aforementioned disadvantages are eliminated by the method according to the invention. In particular, the cutting and direct forming (embossing) of the tooth rows can minimize the punch shrinkage in this region due to the material flow. A further advantage may be that dimensional deviations of the components can be reduced. Furthermore, a greater part area (teiespektrum) can be covered by the method according to the invention than in precision stamping, since precision stamping is limited by the dimensions of the automatic stamping press.

In an advantageous embodiment of the invention, the component is produced in a sequential lamination process (Folgeverbundprozess) from Coil (Coil), i.e. the component is produced in situ. This eliminates the material flow costs necessary according to the prior art, which leads to a cost reduction.

Drawings

The present invention will be described in detail below with reference to examples. The figures belonging thereto show:

figure 1 shows a strip chart (Streifenbild) of a sequential composite tool in top view,

FIG. 2 shows a schematic view of a tool for carrying out a first method variant, an

Fig. 3 shows a schematic view of a tool for performing a second manufacturing variant.

Detailed Description

The component 1 is produced by the method according to the invention and is used for height adjustment of a motor vehicle seat. It has a row of teeth 2 with which a pinion engages in a not shown mounted state, the setting movement of the component 1 being brought about by the drive of the pinion.

Two method variants are explained below. In both method variants, the strip 3 is pulled off from a winding, not shown, and fed to the individual steps.

In a first method variant, the component 1 is cut and formed step by step in a sequential composite process. It has an approximately spoon shape before the manufacture of the tooth row 2, with a shank region 1.1 and an integrally following wider functional region 1.2. In the functional region 1.2, the tooth row 2 is formed with a rough contour by cutting and forming, but it also has a certain undersize (Untermass) or oversize (vornaltemas). This region is then inductively heated in the tool 4 shown in fig. 2 and impressed onto the final contour of the tooth row 2 between an impression punch (praegestpel) 5 and a die (matrix) 6. In this case, the material flows into the defect, so that the press shrinkage is reduced to a minimum in this region. In this phase, which is indicated by a in the strip diagram according to fig. 1, the cooling of the hot component 1 to a certain temperature for the tissue transformation is also effected at the same time. The following method stage provides for further cooling of the component 1 before the latter is shaped in the final geometry in the final correction stage and separated from the strip 3 into the finished product.

In a second method variant, the component 1 is also cut and formed step by step in a continuous composite process. Here, however, the blank shape (Rohform) of the tooth row 2 is not produced, but the functional region 1.2 of the component 1 is inductively heated. The row of teeth 2 is then cut to the final dimensions in the next method stage. In this phase, which is indicated by B in the strip diagram according to fig. 1, cooling of the hot component is also simultaneously effected. Fig. 3 diagrammatically shows a tool 7 for carrying out this method stage. The component 1 is clamped with the heated functional region 1.2 between the lower tool part 8 and the shear punch 9. The shear punch 9 is then pressed down against the tool lower part 8, thereby cutting the final contour of the row of teeth 2. An ejector (Auswerfer)10 is axially movably mounted in the shearing punch 9 and presses the cut component 1 out of the shearing punch 9. In the process, the punching waste 1.3 to be removed, which is located on the lower tool part 8, accumulates.

The following method stages provide for further cooling of the component 1 as in the first method variant.