阅读说明：本技术 在内侧带腐蚀保护的火花塞壳体以及火花塞和其制造方法 (Spark plug shell with corrosion protection on the inside, spark plug and method for producing the same ) 是由 M·皮拉斯基 R·克劳斯 H·诺尔舍尔 S·拉特戈贝尔 G·皮特森 T·贝格曼 M·布林 于 2020-03-02 设计创作，主要内容包括：本发明涉及一种火花塞壳体(2),其具有内侧(24)、外侧(23)和纵轴线,该纵轴线从火花塞壳体(2)的面向燃烧室的端部(21)延伸至火花塞壳体(2)的背离燃烧室的端部(22),其中火花塞壳体(2)在其内侧(24)上具有环绕的凸肩(25),该凸肩设立用于使火花塞绝缘体(3)靠置在该凸肩上,其中,火花塞壳体(2)在其内侧(24)上具有防腐蚀层(50),该防腐蚀层构造在火花塞壳体(2)的内侧(24)的区段(55)上,其中区段(55)从火花塞壳体(2)的面向燃烧室的端部(21)至少延伸越过所述凸肩(25)并且沿着火花塞壳体(2)的内圆周延伸。(The invention relates to a spark plug housing (2) having an inner side (24), an outer side (23) and a longitudinal axis, the longitudinal axis extends from an end (21) of the spark plug housing (2) facing the combustion chamber to an end (22) of the spark plug housing (2) facing away from the combustion chamber, wherein the spark plug housing (2) has a circumferential shoulder (25) on its inner side (24), which is designed to rest the spark plug insulator (3) on the shoulder, wherein the spark plug housing (2) has an anti-corrosion layer (50) on its inner side (24), the anti-corrosion layer is formed on a section (55) of the inner side (24) of the spark plug housing (2), wherein the section (55) extends from the end (21) of the spark plug housing (2) facing the combustion chamber at least over the shoulder (25) and along the inner circumference of the spark plug housing (2).)

1. A spark plug housing (2) having an inner side (24), an outer side (23) and a longitudinal axis, the longitudinal axis extends from an end (21) of the spark plug housing (2) facing the combustion chamber to an end (22) of the spark plug housing (2) facing away from the combustion chamber, wherein the spark plug housing (2) has a circumferential shoulder (25) on its inner side (24), which is designed to rest the spark plug insulator (3) on the shoulder, characterized in that the spark plug housing (2) has an anti-corrosion layer (50) on its inner side (24), the anti-corrosion layer is formed on a section (55) of the inner side (24) of the spark plug housing (2), wherein the section (55) extends from the end (21) of the spark plug housing (2) facing the combustion chamber at least over the shoulder (25) and along the inner circumference of the spark plug housing (2).

2. The spark plug housing (2) according to claim 1, wherein the corrosion protection layer (50) is an electro-plating applied layer.

3. The spark plug housing (2) according to claim 1 or 2, wherein the corrosion protection layer (50) comprises nickel and/or zinc.

4. A spark plug housing (2) according to any one of the preceding claims, characterized in that the corrosion protection layer (50) extends from the shoulder (25) at least 1 mm further in the direction of the end (22) of the spark plug housing (2) facing away from the combustion chamber.

5. The spark plug housing (2) according to any one of the preceding claims, characterized in that the anti-corrosion layer (50) has a thickness D of at least 2 μm on average, in particular along the circumference of the section (55) and/or along the longitudinal extension of the section (55).

6. The spark plug shell (2) according to any one of the preceding claims, wherein the corrosion protection layer (50) has a uniform thickness, the thickness not differing by more than 10% between the thickest and thinnest portions.

7. The spark plug housing (2) according to any one of the preceding claims, wherein the spark plug housing (2) has only a corrosion layer (50) on its inner side (24).

8. The spark plug housing (2) as claimed in one of claims 1 to 6, characterized in that the spark plug housing (2) has, in addition to the corrosion protection layer (50), further layers, in particular one or more intermediate layers and/or sealing layers.

9. A spark plug (1) having a spark plug housing (2) according to one of the preceding claims 1 to 8, a spark plug insulator (3) arranged in the spark plug housing (2), a center electrode (4) arranged in the spark plug insulator (3) and a ground electrode (5) arranged at an end (21) of the spark plug housing (2) facing the combustion chamber, wherein the ground electrode (5) and the center electrode (4) are set up to jointly form a firing gap.

10. A method for manufacturing a spark plug housing (2) according to any one of claims 1 to 8, characterized in that at least one section (55) on the inner side (24) of the spark plug housing (2) is galvanically coated with a corrosion protection layer (50) by placing a coated electrode in the spark plug housing (2).

Technical Field

The invention relates to a spark plug housing according to claim 1 and a spark plug having such a spark plug housing according to claim 9 and a production method for a spark plug housing according to claim 10.

Background

Current spark plug housings typically have a coating on their outside that serves to protect the spark plug housing from corrosion. Typically, such corrosion protection layers are produced by electrochemical or galvanic or other coating methods. Each coating method has its advantages and disadvantages.

Disclosure of Invention

For galvanic coating, the spark plug housing is placed in a drum or held on a holder for the coating. The difficulty here is that the inner side of the spark plug housing cannot be coated or can be coated only to a small extent, since the electric field required for the formation of the layer is shielded in the inner region from the housing itself. In particular, in this method, a spark plug housing with a deep breathing space has no or at least no sufficient and uniform coating on its inside. As a result, the spark plug housing has corroded on its inside in unfavorable storage or transport conditions. The spark plug housing can no longer be used. If corrosion of the breathing space is not noticed and the spark plug housing is used for the spark plug, the spark plug has a significantly shorter service life than a spark plug with a non-corroded spark plug housing.

The object of the invention is to provide a spark plug housing and a spark plug in which corrosion in the breathing space of the spark plug housing is as little as possible.

This object is achieved in the spark plug housing according to the invention in that the spark plug housing has an inner side, an outer side and a longitudinal axis which extends from the end of the spark plug housing facing the combustion chamber to the end of the spark plug housing facing away from the combustion chamber, wherein the spark plug housing has a circumferential shoulder on its inner side which is set up for the spark plug insulator to rest on, wherein the spark plug housing has a corrosion protection layer on its inner side which is formed on a section of the inner side of the spark plug housing, wherein the section extends from the end of the spark plug housing facing the combustion chamber at least over the shoulder and along the inner circumference of the spark plug housing.

The advantage is thereby obtained that the section covered by the corrosion protection layer, which section defines and thus forms the breathing space in the spark plug together with the spark plug insulator, is protected by the corrosion protection layer on the inner side of the spark plug housing, so that it is protected against undesired corrosion both during storage, transport and during use of the spark plug. In this case, it is particularly advantageous if the corrosion protection layer extends from the end of the spark plug housing facing the combustion chamber at least over the shoulder. For a spark plug, the spark plug insulator is located on a shoulder on the inside of the spark plug housing. Frequently, together with the inner seal, but also in some cases without the inner seal, the gap between the spark plug housing and the spark plug insulator is sealed in a gas-tight manner at the shoulder, so that the gas mixture generated in the combustion chamber cannot penetrate further into the spark plug housing beyond the inner sealing point at the shoulder. The breathing space thus extends from the end of the spark plug housing facing the combustion chamber as far as a shoulder, against which the spark plug insulator rests and which normally seals the gap together with an internal seal.

In a further development of the invention, it is provided that the corrosion protection layer is an galvanically applied layer. This means that the corrosion layer is applied to the surface of the spark plug housing by means of an electroplating coating process. In particular with regard to the galvanic coating method, when the coated electrode is placed inside the spark plug housing in the galvanic coating method, a very uniform corrosion protection layer is obtained, which is also configured far enough on the inside of the spark plug housing so that a very uniform electric field is generated along the longitudinal axis of the spark plug housing for the section to be coated.

In addition or alternatively, provision can be made for the corrosion protection layer to comprise nickel and/or zinc. The corrosion layer with or consisting of these elements is very stable. In particular, the corrosion protection layer is free of phosphorous.

In an advantageous embodiment of the invention, it is provided that the corrosion protection layer extends at least 1 mm further from the shoulder in the direction of the end of the spark plug housing facing away from the combustion chamber. This ensures that the corrosion protection layer is formed far enough on the inside of the spark plug housing that there is no direct corrosion at the inner sealing point at the shoulder.

It has proven to be particularly advantageous if the corrosion protection layer has a thickness D of at least 2 μm on average, in particular along the circumference of the section and/or along the longitudinal extent of the section. The thickness D is measured perpendicular to the inner side of the spark plug housing. It has been shown that, at a layer thickness of less than 2 μm, possible defects in the corrosion protection layer can penetrate through the layer from the surface of the corrosion protection layer to the spark plug housing and thus form possible corrosion paths to the surface of the spark plug housing. In the case of a layer thickness of at least 2 μm, the probability of such corrosion paths is sufficiently low for the corrosion protection layer to have a sufficient protective function.

It is furthermore advantageous if the corrosion protection layer has a uniform thickness, which does not differ by more than 10% between the thickest and thinnest point. This prevents the formation of regions that are significantly thinner than the remaining corrosion protection layer. In the thinner regions, the corrosion path from the surface of the corrosion protection layer to the housing is more likely to be present than in the remaining corrosion protection layer. Therefore, the thinner portion is a weak portion and can result in not exhibiting the intended technical effect of the present invention.

In one embodiment of the spark plug housing, the spark plug housing has only a corrosion layer on its inner side. This simplifies the production and production costs of the spark plug housing with good corrosion protection.

In an alternative embodiment of the spark plug housing, the spark plug housing has, in addition to the corrosion protection layer, further layers, in particular one or more intermediate layers and/or sealing layers. The corrosion protection layer, the intermediate layer and the sealing layer form a layer system, i.e. the different layers are arranged on top of one another. In this way, a particularly robust layer system can be provided for corrosion protection of the spark plug housing, which layer system is necessary even for applications of the spark plug under extreme combustion conditions.

The invention further relates to a spark plug comprising a spark plug housing according to the invention, a spark plug insulator arranged in the spark plug housing, a center electrode arranged in the spark plug insulator, and a ground electrode arranged on the end of the spark plug housing facing the combustion chamber, wherein the ground electrode and the center electrode are designed to jointly form an ignition gap.

The above-described advantageous technical effects also work accordingly in the spark plug.

The invention further relates to a method for producing a spark plug housing according to the invention, wherein at least one section of the spark plug housing on the inside is galvanically coated with a corrosion protection layer by means of a coated electrode being placed in the spark plug housing.

The advantage thereby obtained is that in the galvanic coating method a very uniform corrosion protection layer is formed on the inner side of the spark plug housing, which is also formed far enough on the inner side of the spark plug housing. In the galvanic coating method, by placing the coated electrode inside the spark plug housing, a very uniform electric field is obtained for the section to be coated along the longitudinal axis of the spark plug housing. A very uniform corrosion protection layer can thereby be applied to the inner side of the spark plug housing.

Drawings

Further features, application possibilities and advantages of the invention emerge from the following description of an embodiment of the invention, which is illustrated in the figures of the drawings.

Figure 1 shows an example of a spark plug housing according to the invention,

fig. 2 shows a spark plug.

Detailed Description

Fig. 1 shows a spark plug housing 2 according to the invention. The spark plug housing 2 has an inner side 24, an outer side 23, an end 21 facing the combustion chamber and an end 22 facing away from the combustion chamber. A shoulder 25 is formed on the inner side 24 of the spark plug housing 2, which shoulder surrounds the inner side 24. The shoulder 25 is provided for the purpose of placing the spark plug insulator 3 on the shoulder 25 in the spark plug 1 with the spark plug insulator 3.

The corrosion protection layer 50 is applied to the surface of the spark plug shell inner side 24 in a section 55. The corrosion protection layer 50 extends from the end of the spark plug housing facing the combustion chamber over the shoulder 25 and along the inner circumference of the spark plug housing inner side 24 by at least 1 mm. In this example, the corrosion protection layer 50 is formed on a section 55 which has a length of at least 4 mm parallel to the longitudinal axis of the spark plug housing 2. The corrosion protection layer 50 has a layer thickness D which is as uniform as possible and is on average at least 2 μm along its circumference and along its longitudinal extent, wherein the thickest and thinnest points of the corrosion protection layer differ by no more than 10%.

The corrosion protection layer 50 is preferably applied by means of an electroplating coating method, wherein a coated electrode is arranged inside the spark plug housing 2 in order to coat the spark plug housing inner side 24 with the corrosion protection layer 50.

The spark plug housing is typically made of carbon steel, such as C10 or C22.

Fig. 2 shows the spark plug 1 in a half-cut view. The spark plug 1 comprises a spark plug housing 2 having an inner side 24, an outer side 23, an end 21 facing the combustion chamber and an end 22 facing away from the combustion chamber. The spark plug insulator 3 is inserted into the spark plug housing 2. The spark plug housing 2 and the spark plug insulator 3 each have a bore along their longitudinal axis X. The longitudinal axis of the spark plug housing 2, the longitudinal axis of the spark plug insulator 3 and the longitudinal axis of the spark plug 1 coincide. The center electrode 4 is inserted into the spark plug insulator 3. Furthermore, a connecting bolt 8 with a connecting nut extends into the spark plug insulator 3, by means of which connecting bolt the spark plug 1 can be electrically contacted to a voltage source, not shown here. The connecting screw 8 and the connecting nut form the end of the spark plug 1 facing away from the combustion chamber.

The resistance element is located between the center electrode 4 and the connecting bolt 8 in the insulator 3. The resistance element connects the center electrode 4 to the connecting bolt 8 in an electrically conductive manner.

The insulator 3 rests with a projection on a circumferential shoulder 25 formed on the inner side 24 of the spark plug housing 2. In order to seal the air gap between the spark plug housing inner side 24 and the insulator 3, an inner seal is arranged between the insulator nose and the shoulder 25, which inner seal is plastically deformed when the spark plug insulator 3 is clamped in the spark plug housing 2 and thereby seals the air gap.

On the spark plug housing 2, a ground electrode 5 is arranged in an electrically conductive manner at its combustion chamber-side end 21. The ground electrode 5 and the center electrode 4 are arranged relative to one another in such a way that an ignition gap is formed between them, at which an ignition spark is generated.