Titanium adhesive bonding: Difference between revisions
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Abiluabilu (talk | contribs) Added laser roughened Ti contact angle measurement image. |
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Topic 1: Silane primer applications for thermoset epoxy bonding of thermoplastic polyurethanes to titanium surfaces. Discuss types of surface roughening to reduce the contact angle of the titanium, primer shelf life, application techniques, and curing temperatures. |
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Topic 2: Surface treatments of thermoplastic polyurethanes to improve thermoset epoxy bonding. Discuss the difference between corona, plasma, and IPA ultrasonic cleaning to reduce the contact angle and shelf life. |
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Topic 3: Contact angle measurement techniques. Discuss available goniometers, how they work, and test method validations. |
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Topic 4: Surface roughness techniques to improve adhesion to Grade 1 through 5 titanium. Discuss laser roughening using a fiber laser, the difference between Ra and Sa/Sdr surface measurements, and surface cooling methods. |
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2/25/2018: I'll go with Topic 4, surface roughness techniques to improve adhesion of thermoset epoxy to medical grade titanium. |
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Outline: |
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Methods for Surface Preparation of Titanium for Adhesive Bonding |
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Introduction: Discuss where Titanium is used in industry. Describe Titanium's oxide layer. |
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Testing of adhesion strength: Discuss the wedge test and how to precondition and exercise the bond joint. |
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Measuring surface roughness: Ra, Sa and Sdr. |
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Chemical methods: |
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Abrasive methods: Grit blasting with silicon carbide , sodium bicarbonate, alumina, and glass beads. |
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Etching: |
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Anodizing: |
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Laser roughening: |
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Primer application: |
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References: |
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Draft 3/25/2018: I plan to add images that I own in the laser roughening section that show Grade 1 titanium SEM analysis post processing. |
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'''<u>Methods for Surface Preparation of Titanium for Adhesive Bonding</u>''' |
'''<u>Methods for Surface Preparation of Titanium for Adhesive Bonding</u>''' |
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'''Laser Roughening:''' |
'''Laser Roughening:''' |
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[[File:Contact Angle of Laser Roughened Ti.png|thumb|Grade 1 Ti Laser Roughened Contact Angle Measurement.]] |
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Laser roughening of titanium surfaces for epoxy bonding is a good option when abrasives are restricted in the manufacturing area. The process is also more repeatable and consistent than the often manual abrasive blasting. Other advantages over abrasives are touch time and maintenance. The drawback of laser roughening is the cost of the equipment and tooling. Also, the laser will heat the material depending on its power output and number of passes. It will remove material from the surface and create regions of hardened material that get relocated within the surface. Neodymium doped yttrium aluminum garnet (Nd:YAG), CO<sub>2,</sub> green, femtosecond lasers can be used depending on the workpiece and adhesion requirements. YAG or fiber laser markers that anneal the titanium surface are the low cost solution while the femtosecond laser is on the high end of the cost scale. Surface roughness of laser roughened surfaces is best measured using a three-dimensional scanning laser microscope or a non-contact profilometer. XPS and SEM analysis of alloyed titanium, like grade 5, will show the segregation of the aluminum and vanadium. Often times, the laser roughening is done in ambient conditions with orr without argon shielding gas. Ambient elements that play no role in bonding like carbon and nitrogen can be ignored from the surface analysis. Laser roughening of grade 5 titanium will show that the vanadium will segregate to the bulk of the alloy and appear at the surface with an increased oxygen level. Lap shear tests have shown that this segregation does not affect surface adhesion. The increase of laser power has shown to increase oxidation of grade 5 titanium which has been correlated to increase bond strength.<ref>Palmieri et al. Laser Ablation Surface Preparation of Ti-6Al-4V for Adhesive Bonding. NASA Langley Research Center; Hampton, VA, United States, 2012. </ref> Also, producing alumina at the surface has shown to improve bonding. Depending on the grade of titanium and the adhesive used, the laser parameters of power, frequency, and pattern can be tailored to the loading requirements and the aforementioned surface elemental beneficial conditions. Unwanted metal oxide can occur when higher laser powers and multiple passes are employed. These can be removed with a lower powered laser pass or a titanium brush, post roughening. The grain size will affect the surface roughness, hardness, and wettability of the surface. On grade 2 titanium, a smaller grain improved these surface prep characteristics.<ref>H. Garbacz et al. The effect of grain size on the surface properties of titanium grade 2 after different treatments. Surface & Coating Technology, May 2017. Pages 13-24. </ref> As with abrasives, a silane primer application is used to seal the laser roughened surface. |
Laser roughening of titanium surfaces for epoxy bonding is a good option when abrasives are restricted in the manufacturing area. The process is also more repeatable and consistent than the often manual abrasive blasting. Other advantages over abrasives are touch time and maintenance. The drawback of laser roughening is the cost of the equipment and tooling. Also, the laser will heat the material depending on its power output and number of passes. It will remove material from the surface and create regions of hardened material that get relocated within the surface. Neodymium doped yttrium aluminum garnet (Nd:YAG), CO<sub>2,</sub> green, femtosecond lasers can be used depending on the workpiece and adhesion requirements. YAG or fiber laser markers that anneal the titanium surface are the low cost solution while the femtosecond laser is on the high end of the cost scale. Surface roughness of laser roughened surfaces is best measured using a three-dimensional scanning laser microscope or a non-contact profilometer. XPS and SEM analysis of alloyed titanium, like grade 5, will show the segregation of the aluminum and vanadium. Often times, the laser roughening is done in ambient conditions with orr without argon shielding gas. Ambient elements that play no role in bonding like carbon and nitrogen can be ignored from the surface analysis. Laser roughening of grade 5 titanium will show that the vanadium will segregate to the bulk of the alloy and appear at the surface with an increased oxygen level. Lap shear tests have shown that this segregation does not affect surface adhesion. The increase of laser power has shown to increase oxidation of grade 5 titanium which has been correlated to increase bond strength.<ref>Palmieri et al. Laser Ablation Surface Preparation of Ti-6Al-4V for Adhesive Bonding. NASA Langley Research Center; Hampton, VA, United States, 2012. </ref> Also, producing alumina at the surface has shown to improve bonding. Depending on the grade of titanium and the adhesive used, the laser parameters of power, frequency, and pattern can be tailored to the loading requirements and the aforementioned surface elemental beneficial conditions. Unwanted metal oxide can occur when higher laser powers and multiple passes are employed. These can be removed with a lower powered laser pass or a titanium brush, post roughening. The grain size will affect the surface roughness, hardness, and wettability of the surface. On grade 2 titanium, a smaller grain improved these surface prep characteristics.<ref>H. Garbacz et al. The effect of grain size on the surface properties of titanium grade 2 after different treatments. Surface & Coating Technology, May 2017. Pages 13-24. </ref> As with abrasives, a silane primer application is used to seal the laser roughened surface. |
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[[File:Laser Roughening.png|thumb|Commercially pure titanium roughened using a fiber laser .001 inch spacing, 100 inches/second speed - 500X magnification. ]] |
[[File:Laser Roughening.png|thumb|Commercially pure titanium roughened using a fiber laser .001 inch spacing, 100 inches/second speed - 500X magnification. ]] |
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Revision as of 05:09, 30 March 2018
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Methods for Surface Preparation of Titanium for Adhesive Bonding
Titanium is often used in medical and military applications because of its strength, weight, and corrosion resistance characteristics. In implantable medical devices, titanium is used because of its biocompatibility and its passive, stable oxide layer.[1] Also, titanium allergies are rare and in those cases mitigations like parylene coating are used.[2] In the aerospace industry titanium is often bonded to to save cost, touch times, and the need for mechanical fasteners. In the past, Russian submarines hulls were completely made of titanium because the non-magnetic nature of the material went undetected by the defense technology at that time. This article will discuss surface preparation for adhesive bonding to titanium. There is not a single solution for all applications. For example, etchant and chemical methods are not biocompatible and cannot be human used in the blood and tissue contact. Mechanical surface roughness techniques like sanding and laser roughening may make the surface brittle and create micro-hardness regions that would not be suitable for cyclic loading found in military applications.
Abrasives:
Aluminum Oxide or Alumina and Silicon Carbide are most commonly used to pretreat titanium for epoxy bonding. Alumina has a hardness of 9 on the Mohs’ scale while silicon carbide has a hardness of just under that of a diamond. Alumina particle sizes in the 10 to 150 micron range are used depending on the workpiece geometry and blasting capabilities. Silicon carbide particles are typically in to 20 to 50 micron range with texturing occurring at a faster pace than alumina. When silicon carbide hits the titanium surface the operator will see sparks as is common with titanium surfaced golf drivers when they hit the ground surface. Care must be used if sensitive electronic assemblies are housed within the titanium enclosure. Electrostatic discharge can be mitigated with point ionizers or grounding features in the tools. Glass beads media are used less commonly. They come as spherical particles in the 35-100 micron range. They are a 6 on the Mohs’ scale and are often times used with water to create a hydrohone slurry. When applied to commercially pure titanium material they will stress relieve the assembly, typically after welding, and create a satin-like finish perfect for laser marking of labels. The surface is also suitable as a pretreatment for assemblies prior to vapor deposition of parylene coating.[3]
Surface roughness is achieved through the use of a blasting nozzle propelled by compressed air. The focus and velocity of the media created by the nozzle can be varied depending on the roughness requirements and repeatability. Surface roughness measured using Ra, Sa and Sdr is used the characterize the media application and the adhesive bonding strength. Typical Ra values for commercially pure titanium are between 0.2 and 0.75 micro meters.[4] The surface roughness can be tailored to the epoxy viscosity and curing conversion. The roughened surface is often sealed with a primer application like Silane A-187. Application of the primer can be achieved through manual means, like a brush. It can also be sprayed on the roughened surface or the whole assembly can be dipped in a primer solution and cured. On commercially pure titanium surfaces that have been roughened with silicon carbide, a silane primer will darken the surface allowing for verification of application.
Implantable medical devices are often manufactured in a cleanroom environment. Typical cleanroom ratings are within the ISO-7 and ISO-8 range or between class 10k and 100k. Abrasives and their application cannot be housed in such cleanrooms. If pass through windows are not available the laser roughening is a good option.
Laser Roughening:
Laser roughening of titanium surfaces for epoxy bonding is a good option when abrasives are restricted in the manufacturing area. The process is also more repeatable and consistent than the often manual abrasive blasting. Other advantages over abrasives are touch time and maintenance. The drawback of laser roughening is the cost of the equipment and tooling. Also, the laser will heat the material depending on its power output and number of passes. It will remove material from the surface and create regions of hardened material that get relocated within the surface. Neodymium doped yttrium aluminum garnet (Nd:YAG), CO2, green, femtosecond lasers can be used depending on the workpiece and adhesion requirements. YAG or fiber laser markers that anneal the titanium surface are the low cost solution while the femtosecond laser is on the high end of the cost scale. Surface roughness of laser roughened surfaces is best measured using a three-dimensional scanning laser microscope or a non-contact profilometer. XPS and SEM analysis of alloyed titanium, like grade 5, will show the segregation of the aluminum and vanadium. Often times, the laser roughening is done in ambient conditions with orr without argon shielding gas. Ambient elements that play no role in bonding like carbon and nitrogen can be ignored from the surface analysis. Laser roughening of grade 5 titanium will show that the vanadium will segregate to the bulk of the alloy and appear at the surface with an increased oxygen level. Lap shear tests have shown that this segregation does not affect surface adhesion. The increase of laser power has shown to increase oxidation of grade 5 titanium which has been correlated to increase bond strength.[5] Also, producing alumina at the surface has shown to improve bonding. Depending on the grade of titanium and the adhesive used, the laser parameters of power, frequency, and pattern can be tailored to the loading requirements and the aforementioned surface elemental beneficial conditions. Unwanted metal oxide can occur when higher laser powers and multiple passes are employed. These can be removed with a lower powered laser pass or a titanium brush, post roughening. The grain size will affect the surface roughness, hardness, and wettability of the surface. On grade 2 titanium, a smaller grain improved these surface prep characteristics.[6] As with abrasives, a silane primer application is used to seal the laser roughened surface.
Etchant, Chemical and Anodize Pretreatments:
Prior to these treatments a solvent degreaser should be used with an alumina grit blast to remove unwanted oxides on the surface. A 1982 study at the Naval Air Development Center compared 11 etchant, chemical and anodize pretreatments on grade 5 titanium samples. Once bonded, these samples were exposed to 56 days of 140 degrees F and 100% relative humidity. Crack growth was measured at preselected intervals. The results showed that chromic acid anodize with fluoride, etchants Turco 5578, Pasa Jell 107C – hydrophone, Pasa Jell 107M – dry hone, Dapcotreat 4023/4000 and alkaline peroxide were superior to phosphate fluoride pretreatments.[7]
Turco 5578-L is a commonly used etchant and alkaline cleaner for titanium. It is produced by Henkel Technologies and comes in a liquid form so concentrations can be easily modified. It is an anisotropic etchant that avoids hydrogen embrittlement.[4]
References:
- ^ Linjiang Chai et al. Microstructural characterization and hardness variation of pure Ti surface-treated by pulsed laser. Journal of Alloys and Compounds, January 2018. Pg. 116-122.
- ^ "A New Look at Parylene Conformal Coatings".
{{cite web}}: Cite has empty unknown parameter:|dead-url=(help) - ^ "Microblasting Nozzles and Abrasive Media" (PDF).
{{cite web}}: Cite has empty unknown parameter:|dead-url=(help) - ^ a b S. Zimmermann et al. Improved adhesion at titanium surfaces via laser-induced surface oxidation and roughening. Materials Science & Engineering, August 2012. Pg. 755-760.
- ^ Palmieri et al. Laser Ablation Surface Preparation of Ti-6Al-4V for Adhesive Bonding. NASA Langley Research Center; Hampton, VA, United States, 2012.
- ^ H. Garbacz et al. The effect of grain size on the surface properties of titanium grade 2 after different treatments. Surface & Coating Technology, May 2017. Pages 13-24.
- ^ S.R. Brown and G.J. Pilla, Titanium Surface Treatments for Adhesive Bonding, Naval Air Development Center Warminster, Pa 1982.
Instructor Comments
Looks like you are interested in adhesive bonding of TPU to titanium. Then why not write an overview article on the topic, including typical adhesives, brief description of possible surface preparation for the TPU and titanium, and applications?
Regarding topic 3, there is already a Wikipedia article that discusses methods to measure contact angle, see https://en.wikipedia.org/wiki/Contact_angle#Measuring_methods
Please let me know which topic you select. Thanks!