TH2157A - A process for tear resistance of threaded parts when they are assembled or removed. - Google Patents

Abstract

A tear-resistant process for two collaborative threaded parts (10,16) was prepared. The process consists of bonding a thin layer of material (36) by plastering high energy ions onto the machined surface (12,14) of at least one of the threaded parts (10,16) to provide Achieved a thin mechanical protection layer (36) on threaded parts (10,16) with low shear stress values.

Claims (9)

1.Technology for tear resistance, threaded parts that work together include: Cohesion of the material with high-energy ion putty onto the machine edge of at least one part to achieve a thin mechanical protective layer. On metal surfaces, metal synergies with low shear stress induce metal-metal surface separation. Working together from each other to prevent tearing and Rotate at least one of the threaded parts during gripping of the thin piece. To get a thin, even layer 2. Procedures requested for claim 1 in which the thin layer They are in class including gold, silver, lead, tin, indium, and copper. 3. The process as requested for claim 1, where the captured layer reaches its thickness ranges from approximately 1,000 angstroms to approximately 1 mm. 4.Technologies for tear resistance of threaded interlocking parts include: Cohesion where a large number of layers of the material layer is applied high energy ions onto the machine edge of at least one counterpart to obtain a thin mechanical protective layer. The inner layer is more rigid than the one above the co-working metal-metal substrate with low shear stress, creating a separation of the co-working metal-metal substrate to prevent tearing. 5. Process according to the claim in claim 4, in which the thin layer They are in class including gold, silver, lead, tin, indium, and copper. 6. The process as requested by claim 4, where the bulk of the layers in the range and thickness ranges from approximately 500 angstroms (angstroms) to approximately 6 mm. 7. Process according to the claim in claim 4, in which the thin layer The inner layer is chromium and a thin layer. The outer layer is gold. 8. The process according to claim 7, where the thickness of the chromium layer is approximately 2,000 angstroms to approximately 4,000 angstroms and the outer gold layer is approximately 2,000 angstroms. 9. Methods for tear resistance of joint threaded parts include: The adhesion of the material with the thin layer It is an inorganic compound with a layered lattice by plastering high-energy ions onto the machine edge of at least one component for a thin mechanical protective layer. On metal-metal substrates that work together with low shear stress, the separation of cooperative metal-metal substrates to prevent tearing.1 0. Processes to resist tearing of joint threaded parts include: The adhesion of the material with the thin layer It is a pelladium by plastering high energy ions on the machine edge of at least one part, resulting in a thin mechanical bottom shield. On metal-metal surfaces Working together with low shear stress results in the separation of metal substrates that work together with each other to prevent tearing. 1. The method for which the claim is made 10, where the thin layer of palladium includes the palladium alloy 1. 2. Processes for resistance to tearing of joint threaded parts include: The adhesion of the material with the thin layer It is a nickel whose underside is covered with an outer layer by plastering high-energy ions onto the machine edge of at least one component for a thin mechanical protective layer. On metal surfaces - metal at Working together with low shear stress resulting in surface separation Metals - metals that work together from each other to prevent tearing 3.Processes for tear resistance of joint threaded parts include: The adhesion of the material with the thin layer It is an alloy containing gold and copper by plastering high energy ions onto the machine edge of at least one part to achieve a thin mechanical protective layer on the metal-metal co-working surface with stress values. Low shear results in separation of metal-metal surfaces that work together from each other to prevent tearing. 4.Processes for resistance to tearing of joint threaded parts include: The adhesion of the material with the thin layer It is an alloy containing palladium and copper by plastering high-energy ions onto the mechanical edge of at least one component for a thin mechanical protection layer. On metal-metal substrates that work together with low shear stress, the separation of metal-metal substrates that work together to prevent tearing 1 5. Processes for resistance to tearing of joint threaded parts include: The adhesion of the material with the thin layer It is an alloy containing palladium and gold by plastering high energy ion levels onto the machine edges of at least one component to obtain a thin mechanical protective layer. On a metal surface - the metal is made The low shear stress combination results in the separation of metal-metal substrates that work together from each other to prevent tearing.1 6. Processes for resistance to tearing of joint threaded parts include: The adhesion of the material with the thin layer It is an alloy of palladium and silver by plastering high-energy ions onto the mechanical edge of at least one part to obtain a thin mechanical protective layer. On metal-metal substrates that work together with low shear stress, the separation of metal-metal surfaces that works with each other to prevent tearing.1 7.Processes for tear resistance of joint threaded parts include: The adhesion of the material with the thin layer Including refractory materials hardened of metal oxides by plastering high energy ions onto the machine edge of at least one part to obtain a thin mechanical protective layer. On metal-metal substrates that work together with low shear stress, the separation of metal-metal surfaces working together from each other is created. To prevent tearing 1 8. Procedures for the resistance of injection of interlocking threaded parts include: The adhesion of the material with the thin layer Includes refractory ceramic materials that are hardened by plastering high energy ions onto the machine edge of at least one part to obtain a thin mechanical protection layer. On metal-metal substrates that work together with low shear stress, the separation of metal-metal surfaces working together from each other is created. To prevent tearing 1 9. Process according to the right to claim 18 where the ceramic material is Mention includes metal carbides 2 0. The process as requested by Clause 18, where the aforementioned ceramic material includes metal nitride 2. 1. Ion plastering process at both ends of a long cylindrical part consisting of Surrounding each end in the room The removal of air from a room Thus, the air exits from both chambers through the putty evaporation piece in each vented chamber closer to the tip. Provides negative bias of direct current to the part for attracting the positive ions of the evaporated putty. 2. The process for which the right to claim 21 is applied, including the rotation of the part 2 3. Procedures required for claim 21 where a magnetic field is placed close to both ends. 4. Procedures required by claim 21, including enclosing the enclosures of rotating parts in a partition near one of the ventilated chamber 2. 5. Procedures for which the right to claim 14 in which the partition near the area is ventilated is pumped down. And the partition next to it was shielded by inert gas 2 6. The ion plastering process, both ends of a long cylindrical part consisting of a one end encircling in a chamber, with a second end positioned outside such a chamber, the second end of the part with a can Rotatable Evacuation of the room Therefore, the air from approximately both ends. Evaporate the putty in the aeration area near the tip. And give a direct current negative bias to the part for attracting the positive ions of the evaporated putty. 7. The process for which the right to claim 26 includes rotation of the cylinder part 2. 8. Process as requested 26 including placing a magnetic field near each end of the part 2. 9. Method for which the claim is made to claim 26 where evaporation is within the second end and outside the first end 3. 0. The process as requested by claim 28 where a magnetic field is provided by a magnet positioned within each end of the part.