Glidcop

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Glidcop is the registered trademark name of North American Hoganas, Inc. that refers to a family of copper-based metal matrix composite (MMC) alloys mixed primarily with aluminum oxide ceramic particles. The addition of small amounts of aluminum oxide has minuscule effects on the performance of the copper at room temperature (such as a small decrease in thermal and electrical conductivity), but greatly increases the copper's resistance to thermal softening and enhances high elevated temperature strength. The addition of aluminum oxide also increases resistance to radiation damage. As such, the alloy has found use in applications where high thermal conductivity or electrical conductivity is required while also maintaining strength at elevated temperatures or radiation levels.[1]

Properties

Composition and Physical Properties

Glidcop is available in several grades which have varying amounts of aluminum oxide content.

Composition and physical properties of various grades of Glidcop compared to oxygen-free copper (OFC) (at room temperature unless otherwise noted).[1][2]
Grade Aluminum Oxide
Content
UNS Alloy Number Melting Point Density Electrical
Conductivity
Thermal
Conductivity
Coefficient of Thermal Expansion
(range 20-150 °C, 68-300 °F)
Modulus of
Elasticity
OFC 0% - 1,083 °C (1,981 °F) 8.94 g/cm3
(0.323 lb/in3)
58 Meg S/m
(101 % IACS)
391 watt/m/°K
(226 BTU/ft/hr/°F)
17.7 µm/m/°C
(9.8 µ-in/in/°F)
115 GPa
(17 Mpsi)
Glidcop AL-15 0.3 wt. % UNS-C15715 1,083 °C (1,981 °F) 8.90 g/cm3
(0.321 lb/in3)
54 Meg S/m
(92 % IACS)
365 watt/m/°K
(211 BTU/ft/hr/°F)
16.6 µm/m/°C
(9.2 µ-in/in/°F)
130 GPa
(19 Mpsi)
Glidcop AL-25 0.5 wt. % UNS-C15725 1,083 °C (1,981 °F) 8.86 g/cm3
(0.320 lb/in3)
50 Meg S/m
(87 % IACS)
344 watt/m/°K
(199 BTU/ft/hr/°F)
16.6 µm/m/°C
(9.2 µ-in/in/°F)
130 GPa
(19 Mpsi)
Glidcop AL-60 1.1 wt. % UNS-C15760 1,083 °C (1,981 °F) 8.81 g/cm3
(0.318 lb/in3)
45 Meg S/m
(78 % IACS)
322 watt/m/°K
(186 BTU/ft/hr/°F)
16.6 µm/m/°C
(9.2 µ-in/in/°F)
130 GPa
(19 Mpsi)

Additional materials and elements can be added if lower thermal expansion is required, or higher room temperature and elevated temperature strengths. The hardness can also be increased. A composite material of Glidcop AL-60 and 10% Niobium provides high strength and high conductivity. The hardness is comparable to many copper-beryllium and copper-tungsten alloys, while the electrical conductivity is comparable to RWMA Class 2 alloy. Other additives for specialized applications include molybdenum, tungsten, Kovar, and Alloy 42.[1]

At elevated temperatures, Glidcop maintains its strength much better than oxygen-free copper. The aluminum oxide particles in the copper block dislocation movement, which retards recrystallization and prevents grain growth. At 500 °C (932 °F) Glidcop AL-15 has a yield strength of over 29 ksi (200 MPa). Glidcop also has exceptional elevated temperature stress rupture strength when compared to oxygen-free copper.[1]

Glidcop also has excellent resistance to softening after exposure to elevated temperatures.[1]

Post Neutron Irradiated Properties

Glidcop is resistant to degradation by neutron irradiation. For samples irradiated by neutrons at 411 °C (772 °F) and cooled to room temperature, the tensile strengths, swelling, and electrical conductivity were greater than that of pure copper. For samples irradiated from 0 to 150 dpm (displacements per atom), the tensile strength was nearly consistent, while the pure copper experienced a linear decrease in tensile strength on the range from 0 to 50 dpm. For sample swelling, the Glidcop had no noticeable swelling to 150 dpm while the pure copper had a linear growth to approximately 50 dpm, where swelling was 30% of the original. For electrical conductivity, both the pure copper and Glidcop experienced linear drops in performance, though the Glidcop was less affected by the radiation.[1]

Workability

Glidcop material is often acquired with a layer of cladding, typically 10 - 15% of the cross-sectional area of the stock piece, though this varies depending on the production process. The cladding, which is a remnant of the extrusion process often used with Glidcop, must be machined (usually by milling or grinding) off the stock piece in order to take full advantage of the Glidcop properties. After the cladding is removed, machining and working with Glidcop is similar to that of pure copper.[3]

Joining Glidcop material through brazing can be somewhat difficult. Brazing with silver based braze alloys can lead to problems due to the excessive diffusion of silver along grain boundaries. This is often circumvented by first electroplating the Glidcop part with either copper or nickel.[4] The copper plating is often done in a copper cyanide solution since other solutions were found to be problematic. Brazing alloys used include 3565 AuCu and 5050 AuCu, which are used in a dry hydrogen atmosphere.[5][6]

Glidcop also has excellent cold workability. Cold working by drawing, cold heading, or cold forming increase strength while reducing ductility.[1]

Applications

Glidcop has been successfully applied to resistance welding electrodes to reduce stick to galvanized and other coated steels, and in incandescent light bulb leads by resisting softening after exposure to high temperatures. Likewise, Glidcop has found used in relay blades and contactor supports. The alloy's ability to maintain strength after high temperature brazing has led to use in hybrid circuit packages. Furthermore, it has found use in other high temperature applications such as x-ray tube components, and heat exchanger sections for fusion power and synchrotron units. Other uses include high field magnetic coils, sliding electrical contacts, arc welder electrodes, electronic leadframes, MIG contact tips, commutators, high speed motor and generator components, and microwave power tube components.[1]

One of the more intensive uses of Glidcop has been in particle accelerator components, where the alloy may be subjected to high temperatures and high radiation simultaneously. Examples include Radio Frequency Quadrupoles (RFQs) and Compact Absorbers for High-Heat-Load X-ray Undulator Beamlines.[7][8]

See also

References

  1. 1.0 1.1 1.2 1.3 1.4 1.5 1.6 1.7 "GLIDCOP (SCM Product Literature, 1994)". SCM Metal Products. Retrieved 2009-01-14. 
  2. Zhibi Wang. "Thermophysical and Mechanical Properties for Glidcop". Argonne National Laboratory (Intra-Laboratory Memo). Retrieved 2009-01-14. 
  3. Brad Swogger. "Cladding Thickness". SCM Metal Products, Inc. Retrieved 2009-03-10. 
  4. Prasan K. Samal. "Brazing and Diffusion Bonding of GLIDCOP". SCM Metal Products, Inc. Retrieved 2009-03-10. 
  5. "Brazing of Glidcop - SLAC Procedure". SLAC National Accelerator Laboratory. Retrieved 2009-03-10. 
  6. W. Toter; S. Sharma. "Analysis of Gold-Copper Braze Joints in Glidcop for UHV Components at the Advanced Photon Source". Argonne National Laboratory. Retrieved 2009-03-10. 
  7. Ratti, A.; R. Gough, M. Hoff, R. Keller, K. Kennedy, R MacGill, J. Staples (1999). "The SNS RFQ Prototype Module". Particle Accelerator Conference, 1999. 2 (1): 884–886. doi:10.1109/PAC.1999.795388. ISBN 0-7803-5573-3. 
  8. Mochizuki, T.; Y. Sakurai, D. Shu, T. M. Kuzay, H. Kitamura (1998). "Design of Compact Absorbers for High-Heat-Load X-ray Undulator Beamlines at SPring-8". Journal of Synchrotron Radiation 5 (4): 1199–1201. doi:10.1107/S0909049598000387. PMID 16687820. 

External links

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