Patent Application
20070254760
The present invention provides a corrosion resistant roller chain which retains its corrosion resistant propertied for a long period of time under corrosive atmospheres such as saltwater, acid, alkali, and the like. Furthermore, the roller chain has improved endurance at an inexpensive manufacturing cost by reducing the frequency of chain failures due to inflexibility caused by white rust buildup and by reducing the peeling off of the coating on the pin press-fitted areas and the bush fitted areas during the use and/or assembly of the chain. Additionally, the chain of the instant invention can be colored black.
The corrosion resistant roller chain of the instant invention may comprise a pair of right and left inner plates, a bush press-fitted between the inner plates, a roller loosely fitted on the bush, a pair of right and left outer plates disposed on both outer sides of the inner plates, and a connecting pin loosely penetrated through the bush and press-fitted between the outer plates. The outer plates and inner plates may be subjected to a zinc-aluminum system alloy coating by hot-dipping before assembly of the chain. The zinc-aluminum coating may be thinner than required by JIS coverage. For example, the zinc-aluminum system alloy coating may be less than 350 g/m2 (i.e., a film thickness of about 50 μm or more). The coating formed by JIS H 8641 forms an integrated alloy layer of diffused zinc from the zinc-aluminum system coating and iron from the iron base material at the interface between the zinc-aluminum system coating and the outer plate and the inner plate. The adhesion properties of the zinc-aluminum system alloy coating with the iron is superior. Accordingly, peeling of the zinc-aluminum system alloy coating from the iron does not occur at pin press-fitted areas of the outer plate and bush fitted areas of the inner plate during assembly of the chain and during coupling and decoupling of the chain, in contrast to other coatings. Additionally, even if a flaw occurs at a pin fastening riveted area of the outer plate where coating peeling often occurs and the iron of the outer plate is exposed for a long period of time, rust does not form due to the electrochemical protection due to the ionizing of peripheral zinc. This effect is sometimes referred to as sacrificing corrosion-preventive action of zinc-aluminum system alloy coating. These corrosion preventive effects of the instant invention withstand corrosive conditions such as saltwater, acid, alkali, and the like for a long period of time.
Inasmuch as the outer plate and the inner plate are subjected to a thinner film of zinc-aluminum system alloy coating than provided with a coverage of 350 g/m2 (film thickness of about 50 μm or more) as specified by JIS H 8641, the clearance between the outer plate and the inner plate is ensured. Thus, the chain retains full flexibility and, as an effect, the chain has high endurance, at an inexpensive manufacturing cost.
The outer plate and the inner plate of the chain may also be subjected to a chemical conversion coating. The coating may be by chemical conversion treatment in a laminated state, thereby resulting in the chemical conversion coating completely covering the zinc-aluminum system coating. The chemical conversion coating further protects against the generation of rust on the outer plate or the inner plate. Furthermore, the chemical conversion treatment allows for the chain to be colored, such as black. For example, the outer plate and inner plate may be dipped into an alkaline aqueous solution, thereby producing black coloring which can increase the commercial value of the chain.
The bush and connecting pin may be subjected to a nickel coating before the assembly of the chain. The nickel coating can be performed by electroless nickel plating. This increases the hardness of the bush and the connecting pin so that they are more resistant to wear.
As stated hereinabove, the adhesion properties of the zinc-aluminum system alloy coating specified by JIS H 8641 with the iron material of the chain components is improved as the diffused zinc from the zinc-aluminum system alloy coating and diffused iron from the iron basic material form an interface between the zinc-aluminum system alloy coating and the iron basic material of the roller. Therefore, in contrast to conventional chains, peeling of the zinc-aluminum system alloy coating does not occur at the inner circumferential surfaces of a roller opposed to the bush or at the outer circumferential surface of the roller, which comes into contact with a chain guide or the like during the use of the chain. Inasmuch as the coating integrity is maintained, the high corrosion resistant properties of the chain are maintained under corrosion conditions such as saltwater, acid, alkali or the like for a long period of time. Furthermore, the roller comprises a zinc-aluminum system alloy coating that is thinner than a coverage of 350 g/m2 (film thickness of about 50 μm or more) as specified by JIS H 8641. As such, the clearance between the bush and the inner circumferential surface of the roller is ensured, thereby allowing for smooth rolling travel of the roller. Additionally, the chemical conversion coating by chemical conversion treatment completely covers the zinc-aluminum system alloy coating, thereby preventing the generation of rust which may occur in a zinc-aluminum system alloy coating of the roller.
The roller may also be subjected to a nickel coating, such as by electroless nickel plating, before an assembly of the chain.
The roller chain of the instant invention: 1) is corrosion resistant under corrosive conditions such as saltwater, acid, alkali, or the like; 2) exhibits corrosion resistance for a long period of time; 3) prevents peeling of the coatings at pin press-fitted areas and bush fitted areas at the time of assembly of the chain, at the time of coupling or decoupling of the chain and at the time of use of the chain; and 4) reduces the occurrence of failures of the chain during use due to a loss in flexibility. The chain of the instant invention also possesses improved endurance at an inexpensive manufacturing cost.
The corrosion resistant roller chain may comprise a pair of right and left inner plates, a bush press-fitted between the inner plates, a roller loosely fitted on the bush, a pair of right and left outer plates disposed on both outer sides of the inner plates, and a connecting pin loosely penetrated through the bush and press-fitted between the outer plates. The outer plates and inner plates may be subjected to a zinc-aluminum system alloy coating by hot-dipping to create a thinner film thickness than required by JIS coverage and then subjected to chemical conversion coating by chemical conversion treatment by lamination.
The zinc-aluminum system alloy used for plating the outer plates, inner plates, rollers and the like, comprises at least zinc and aluminum. The zinc-aluminum system alloy may comprise additional elements such as magnesium and silicon. For example, a three element system alloy comprising zinc, aluminum, and magnesium or a four element system alloy comprising zinc, aluminum, magnesium, and silicon alloy may be used for plating. The presence of additional elements may further improve the corrosion resistant properties of the chain.
The thickness of the zinc-aluminum system alloy coating on the outer plates, the inner plates and rollers in the present invention may be thinner than the coverage of 350 g/m2 (film thickness of about 50 μm or more) specified by JIS H 8641. In a preferred embodiment, the coat thickness is about 10 to about 40 μm.
Furthermore, electroless nickel plating may used for the outer plates, the inner plates and rollers in the present invention. Nickel plating may comprise, without limitation, any one of the group consisting of nickel, nickel-phosphorus alloy, nickel-boron alloy, nickel-phosphorus-boron alloy, and nickel-phosphorus-PTFE composite alloy. The electroless nickel plating increases the hardness of the chain, thereby increasing the wear resistance of the chain.
Chemical conversion treatment may be used on the outer plates, the inner plates and rollers in the present invention. Inorganic/organic system (e.g., silane system, tannin system) chemical conversion treatments may be used. For example, any phosphate treatment wherein the plates are dipped into a zinc phosphate- or manganese phosphate aqueous solution may be used to prevent rust. Additionally, black coloring may be added by dipping the plates in an alkaline aqueous solution. In a particular embodiment, the black coloring is of a calm or subtle tone, which can increase the commercial value of the chain.
However, it should be noted that it is preferable to avoid dipped into aqueous solution containing chromic acid or dichromic acid to cover the objects with chromium oxide because chromium is toxic and presents issues with regard to environmental regulation such as RoHS regulations and the like.
The following example describes illustrative methods of practicing the instant invention and is not intended to limit the scope of the invention in any way.
A representative corrosion preventive roller chain of the present invention is described hereinbelow.
First, a corrosion resistant roller chain 100 of the present example is assembled by connecting chain units in a longitudinal direction of the chain. Each chain unit comprises a pair of right and left inner plates 110, 110; a bush 120 press-fitted between the inner plates 110, 110; a pair of right and left outer plates 130, 130 disposed on both outer sides of the inner plates 110, 110; connecting pin 140 penetrated through the bush 120 and press-fitted between the outer plates 130, 130; and a roller loosely fitted on an outer circumferential surface of the bush 120. Further, in the corrosion resistant roller chain 100, slide contact rotation may be performed under high surface pressure between the bush 120 and the connecting pin 140 and between the bush 120 and the roller 150 during the use of the chain.
The iron surfaces of the inner plate 110 and the outer plate 130 are coated with a zinc-aluminum system alloy (ZA) by hot dipping at a thickness lower than required by JIS. Specifically, a film thickness about 15 μm is used, which is thinner than the coverage of 350 g/m2 (film thickness of about 50 μm or more) specified by JIS H 8641. The zinc-aluminum system alloy coating is covered by a chemical conversion coating (CP) of a film thickness of 5 μm or less by chemical conversion treatment in a laminated state. The conversion coating uninterruptedly covers the zinc-aluminum system alloy coating.
The zinc-aluminum system alloy coating ZA forms an integrated alloy layer obtained by zinc and iron diffused at an interface between the zinc-aluminum system alloy coating ZA and the iron base material of the inner plate 110 and the outer plate 130. The alloy layer improves the adhesion properties with the iron base material. As such, peeling of the zinc-aluminum system alloy coating ZA does not occur at the bush fitted area of the inner plate 110 or the pin press-fitted area of the outer plate 130, either during assembly of the chain or during coupling and decoupling of the chain, in contrast to conventional chains. Further, even if a flaw occurs at a pin fastening riveted area of the outer plate 130, where peeling of the coating most frequently occurs, and the iron base material is exposed for a significant period of time, the generation of rust is prevented by electromagnetic protection due to ionization by the surrounding zinc. This effect may be referred to as a sacrificial action of the zinc-aluminum system alloy coating ZA. These properties allow for sustained protection against corrosion preventive even under corrosive conditions such as saltwater, acid, alkali or the like.
The clearance between the inner plate 110 and the outer plate 130 can be ensured by the use of the thin film of zinc-aluminum system coating ZA of about 15 μm. Smooth flexing of the chain can be ensured by maintaining the clearance and can be realized at an inexpensive manufacturing cost.
The chemical conversion coating CP in the present example is formed by phosphate treatment in which objects are dipped into zinc phosphate- or manganese phosphate aqueous solution for rust prevention. A chemical conversion coating CP of a film thickness of 5 μm or less is formed as a laminate. The chemical conversion coating CP completely covers the zinc-aluminum system alloy coating ZA, thereby preventing the generation of white rust on the zinc-aluminum system alloy coating ZA of the inner plate 110 and the outer plate 130.
The iron base material surface of a roller 150 is subjected to thin filmed zinc-aluminum system alloy coating ZA by hot dipping to form a film thickness of about 15 μm as on such surfaces as the inner plate 110 and the outer plate 130. The plates are subsequently subjected to a chemical conversion coating CP of a film thickness of 5 μm or less by chemical conversion treatment before assembly of the chain.
The zinc-aluminum system alloy coating ZA forms an integrated alloy layer obtained by diffused zinc from the zinc-aluminum system alloy coating ZA and diffused iron from the iron base material of the roller 150 at their interface, whereby the adhesion properties of the zinc-aluminum system alloy coating ZA with the iron base material is improved. As such, peeling of the zinc-aluminum system alloy coating ZA does not occur, in contrast to conventional chains, at an inner circumferential surface of a roller opposed to the bush 120 and at an outer circumferential surface of a roller, which contacts with a chain guide or the like during the use of the chain. The lack of peeling allows for the retention of the anti-corrosion properties under corrosive conditions such as saltwater, acid, alkali or the like for a long period of time. Inasmuch as the roller, before assembly of the chain, comprises a thin film of the zinc-aluminum system alloy coating ZA of a thickness of about 15 μm, the clearance between a bush 120 and an inner circumferential surface of the roller 150 is maintained and a smooth rolling travel of the roller 150 is achieved. Further, since a chemical conversion coating CP by chemical conversion treatment covers the zinc-aluminum system alloy coating ZA, the generation of rust in the zinc-aluminum system alloy coating ZA of the roller 150 is suppressed.
Additionally, the iron surfaces of the bush 120 and the connecting pin 140 can be subjected to a nickel coating NI by electroless nickel plating before assembly of the chain. The process increases the hardness of the bush 120 and the connecting pin 140, thereby increasing the wear resistance of the entire chain. The thickness of the nickel coating NI is preferably about 10 to about 15 μm.
It is noted that as a basic material of the inner plate 110, the outer plate 130, and the roller 150 in the present example, tough steel subjected to hardening and subsequently to tempering at high temperature of 400 to 500° C. may be used. Thus, it is preferred that formation of the zinc-aluminum system alloy ZA is performed at a treatment temperature of 450° C. or less so as not to lose the high temperature tempering effect.
Additionally, carburized steel is subjected to tempering at a lower temperature of 150 to 250° C. After carburization is used for the bush 120 and the connecting pin 140 as the basic iron material, it is preferred that coating at a low treatment temperature is adapted so as to not lose the low temperature tempering effect.
It is noted that although, in the above-descried example, a roller subjected to a thin filmed zinc-aluminum system alloy coating ZA is subjected to a chemical conversion coating CP of a film thickness of 5 μm or less, the same corrosion preventive effect can be obtained even by being subjected to a nickel coating NI of a film thickness of about 10 to about 15 μm by, e.g., electroless nickel plating.
In the corrosion resistant roller chain 100 of the present invention, the outer plate 110 and the inner plate 130 are subjected to a zinc-aluminum system alloy coating by hot-dipping to form a thin film and then subjected to chemical conversion coating CP by chemical conversion treatment in a laminated state before assembly of the chain. The corrosion resistant roller chain 100 of the present invention can exhibit the high corrosion prevention effect for a long period of time under corrosive conditions such as saltwater, acid, alkali or the like and can improve endurance of the chain at an inexpensive manufacturing cost by reducing failure of the chain due to inflexibility. Further, the coating at a pin press-fitted area and a bush fitted area do not peel off during the use of the chain.
While certain of the preferred embodiments of the present invention have been described and specifically exemplified above, it is not intended that the invention be limited to such embodiments. Various modifications may be made thereto without departing from the scope and spirit of the present invention, as set forth in the following claims.
Documents are cited in the foregoing specification in order to describe the state of the art to which this invention pertains. The entire disclosure of each of these citations is incorporated by reference herein.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2006-124114 | Apr 2006 | JP | national |
