This invention relates to a method of depositing an anti-corrosion material onto a surface subject to corrosion, wherein the deposition of the coating is performed during a shot peening process.
Many vehicle components are subject to corrosion, since they are exposed to the environment. In particular, components mounted under the frame of a vehicle are exposed to a harsh environment. Examples include components of the suspension systems for vehicles, which have typically been subject to corrosion. To prevent corrosion, springs, stabilizer bars, torsion bars and other components of the suspension have often been coated with sacrificial metal coatings to increase resistance to corrosion. However, the requirement of an additional coating process is relatively expensive.
Shot peening operations are often performed on the same components which are subject to corrosion. In a shot peening process, metal particles, which are typically steel, are thrown with force against a part to be treated. The shot peened particles harden the outer surface of the part.
In this invention, the deposition of a corrosion resistant coating is performed in conjunction with the shot peening process. Thus, the corrosion resistant coating can be applied with little added cost.
In a disclosed embodiment of this invention, a sacrificial metal coating which resists corrosion is applied to the outer surface of a shot peen particle. The shot peen particle impacts the surface of the part to be treated. Some of the coating remains with the part. At the conclusion of the shot peening process, the sacrificial metal cover the outer surface of the part. This process thus does not require any additional steps for depositing the coating, but instead deposits the coating during the shot peening process that the part must undergo.
In one method, the steel particles from the shot peening chamber are returned through a bath where the coating is deposited onto the particles. The particles are continuously circulated into the shot peening chamber, gathered, coated and returned.
In another embodiment, the shot peen particles could be formed entirely of the sacrificial metal. Of course, a metal which is sufficiently hard to perform the hardening function of the shot peening would be necessary. However, a worker of ordinary skill in this art would be able to select an appropriate alloy for not only depositing the sacrificial metal, but also for performing the shot peening function.
An automotive component within this invention is preferably a component on a vehicle, and more preferably a suspension component. Specific examples would include springs, stabilizer bars, torsion bars, etc. The finished coated component may be somewhat distinct from an otherwise coated part in that the coating may not be of a uniform thickness. That is, since the coating layer is deposited by the inventive shot peening process, rather than a standard coating process the coating, may not be of a uniform thickness, but may be of a more random thickness. The entire outer surface of the component should still be covered.
These and other features of the present invention can be best understood from the following specification and drawings, the following of which is a brief description.
The coating material 34 is preferably a material which will be deposited on component 24, and which provides a sacrificial metal coating to resist corrosion of the component 24. Examples of such materials are cadmium, zinc, or zinc alloys. Typically component 24 is made of steel, and these coating materials provide a good sacrificial metal resistance to corrosion of the underlying steel component 24. Other known sacrificial metal coatings come within the scope of this invention.
As will be appreciated the shot peening operation is controlled to cover the entire outer surface of the part. The shot peening operation may not systematically direct balls at each area, but rather directs a sufficient number of balls at the part that statistically the entire surface of the part will be shot peened. That is, the part as a whole is subjected to a volume of balls for a time period that the provides a high confidence that the entire outer surface will be effectively shot peened, however, as the balls are not specifically controlled along the outer surface, no absolute assurance is provided that every unit area of the outer surface will shot peened to an equivalent extent. Similarly, the shot peening operation will thus ensure that the great majority of the outer surface of the part will be coated by the sacrificial metal coating 56. The part 24 coated in this manner could be said to differ from the prior coated parts in that the coating may not be of a uniform thickness. That is, dependent on the impact angle, and the number of impacts at any one portion of the outer surface, etc. the thickness of the coating may vary across the outer surface of the part 24.
The particle 62 is being directed at the outer surface 46, the particle 64 is impacting the outer surface 46 and the particle 68 has previously impacted and has rebounded away leaving a portion 66 on the outer surface 46. With the
Preferred embodiments of this invention have been disclosed; however, a worker of ordinary skill in this art would recognize that certain modifications would come within the scope of this invention. For that reason, the following claims should be studied to determine the true scope and content of this invention.
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