Chrome Plating Alternative

Thermal Spray

 

Submitted by

William Kalivas

Summer 2003

Emerging Technologies (TECH 3023)

Rogers University

 

 

Table of Contents

Introduction

 

History

 

The Process

 

Thermal Spray Processes

          Arc Spray

          Combustion

          Plasma

          High Velocity Oxygen Fuel

Detonation Gun

          High-Velocity Air-Fuel

 

Why Replace Chrome?

 

Aircraft Systems

          Landing Gear

          Propeller Hubs

 

Industrial Application

          Optical Mirror Surface

            Consistency

            Productivity

          Oil and Natural Gas Tooling

 

Resources

 

 

Introduction

 

For over 60 years, thermal spray has achieved outstanding technological and commercial progress in the aerospace, gas turbine, engineering and biomedical Industries.

The applications of the little known Thermal Spray industry are endless. Every manufactured product in memory either comes in contact, or is impacted by the process. Applications range from aerospace, to farm implements, to down hole tooling, to the pulp and paper industry. There is a tremendous economic benefit from Thermal Spray. In addition to the economic gains, there are ecological pluses associated with Thermal Spray too. Unlike Chrome and similar plating technologies, Thermal Spray “waste” is easily collected, the scrap is sold for profit, (the metals can be reclaimed) and there are no superfund clean up sites to contend with. In addition, the Thermal Spray process allows designers to use less expensive, lighter and more easily processed base materials. A coating under 0.010” thick can easily add corrosion, wear and thermal protection to any base metal.

Early History

 

The metal spraying industry has its beginnings early in the 20^th century when Dr. M.U. Schoop of Zurich, Switzerland, developed the first process for spraying metal and, subsequently, the first equipment to spray metal in wire form. The early commercial applications for the "Schoop Process" or "metallizing" took place in Germany, and later in France. Schoop subsequently sold his rights to a German firm known as Metallizator. It was this firm that made and sold spray units in Europe, England and the United States beginning in the early 1920"s. Among the early U.S. companies to adopt the technology were Metal Coatings Company and Metal-weld of Philadelphia and Metallizing Company of Los Angeles. Early applications included the coating of railroad tank cars, U.S. Navy ship tanks, coal barges and the spraying of the emergency gates for the Panama Canal.

 

Applications for industrial plants accelerated during the "Great Depression," and during this decade the greatest push for what was then known as "flame spraying" occurred. Four entrepreneurs – Larry Kunkler, Rea Axline, Charles Boyden, Sr. and Charles Stipp from the Metallizing Company of America – were largely responsible for pushing metallizing into the American industrial scene. In 1932, Rea Axline (a subsequent founder of Metco) exhibited his company’s "Three-in-one Metallizing Unit" at a meeting of the Galvanizer’s Institute at the Hotel Statler in St. Louis.

Sixteen years later, the American Metallizing Contractors Association, the predecessor of  the International Thermal Spray Association (ITSA), was founded in the same hotel. The meeting was arranged by Walter B. Meyer of St. Louis Metallizing Company and William H Fatka of Metallizing, Inc. of Chicago. Soon they were publishing a newsletter, AMCA News, to share new thermal spray technology information and identify new market opportunities for members.

With the advent of World War II, the American thermal spray industry went into high gear with the members of the association playing a key role in providing the "metallizing" desperately needed for replacement parts for industrial equipment. Walter Meyer and Tom Lufkin of Tranter Manufacturing Company worked with the Army in the China-Burma-India theater; Knowles Smith of Dix Engineering Company worked with the Navy. By the end of the war, "metallizing" was firmly established as a major industrial process. Applications included large elevated water tanks, tuna fishing boats, chemical industry tanks and tank cars, capacitor castings and pipe.

In response to an increasingly sophisticated market, ITSA drew up industry specifications for the application of corrosion-resistant coatings and spelled out the methods of inspection. These specifications were distributed to engineering firms, designers, and educational institutions throughout the world and resulted in increased business opportunities for the entire metallizing industry. The advent of fusible alloys, flame spraying of ceramics and plasma spraying were soon to follow.

In 1976, the association co-sponsored, with the American Welding Society (AWS), the first International National Thermal Spray Conference held in the United States. The event took place in September 1976 in Miami Beach, Florida. Accounts described the event (which drew 515 people from 28 countries) "as the most successful international conference to date." Eight ITSA members presented technical papers at the event, receiving international recognition for their "contributions to the world body of technical knowledge." This event paved the way for ITSA sponsorship of the National Thermal Spray Conference.

ITSA members were also important contributing authors and researchers for the AWS manual, Thermal Spraying – Practice and Theory Application. Published in 1985, this was the first definitive work on thermal spray produced in the United States.

Today, as an organization, ITSA is working to raise the level of awareness of general industry and government on the advanced capabilities of thermal spray technology and the vitally important problems it can solve. Thermal spray applications have moved from a traditional base in aviation to encompass ground-based turbines, automotive, biomedical electronics, highway infrastructure and virtually every industry. According to 1991 figures, the thermal spray market is expected to reach over $2 billion the beginning of year 2000.

The Process

 

The thermal spray coating process takes the energy from the likes of inflammable gas, ionized gas, explosive gas, or electric energy. The thermal spray powder is heated to a point sufficient (not necessarily to melting) that the feed stock will deform on impact. It is propelled by the energy source gas stream at a

Target, that the feed stock literally explodes onto the target, cools and forms a mechanical bond on the surface.

The establishment of the coating on the surface will greatly improve the character of abrasion resistance, erosion resistance, heat resistance, chemical resistance regarding the part and the product. It can also give the character of the electric conductivity, insulation, and thermal conduction control.

 

 

 

 

Schematic Breakdown of the different Thermal Spray Processes

The Thermal Spray Processes

 

Arc Spraying - Electric Arc Wire Thermal Spray Process

 

Schematic Diagram of the Arc Spraying Process

In the Arc Spraying Process a pair of electrically conductive wires are melted by means of an electric arc. The molten material is atomized by compressed air and propelled towards the substrate surface. The impacting molten particles on the substrate rapidly solidify to form a coating. This arc spraying process carried out correctly is called a "cold process" (relative to the substrate material being coated) as the substrate temperature can be kept low during processing avoiding damage, metallurgical changes and distortion to the substrate material.

 

Arc Gun

Arc spray coatings are normally denser and stronger than their equivalent combustion spray coatings. Low running costs, high spray rates and efficiency make it a good tool for spraying large areas and high production rates. Disadvantages of the arc spraying process are that only electrically conductive wires can be sprayed and if substrate preheating is required, a separate heating source is needed.

 

Combustion Powder Thermal Spray Process - Flame Spraying

 

Schematic Diagram of Combustion Powder Thermal Spraying Process

This flame spraying process is basically the spraying of molten material onto a surface to provide a coating. Material in powder form is melted in a flame (oxy-acetylene or hydrogen most common) to form a fine spray. When the spray contacts the prepared surface of a substrate material, the fine molten droplets rapidly solidify forming a coating. This flame spraying process carried out correctly is called a "cold process" (relative to the substrate material being coated) as the substrate temperature can be kept low during processing avoiding damage, metallurgical changes and distortion to the substrate material.

The main advantage of this flame spraying process over the similar Combustion wire spray process is that a much wider range of materials can be easily processed into powder form giving a larger choice of coatings. The flame spraying process is only limited by materials with higher melting temperatures than the flame can provide or if the material decomposes on heating.

 

Combustion Powder Gun

 

 

Powder Thermal Spray Process Plasma Spraying

Schematic Diagram of the Plasma Spraying Process

The Plasma Spraying Process is basically the spraying of molten or heat softened material onto a surface to provide a coating. Material in the form of powder is injected into a very high temperature plasma flame, where it is rapidly heated and accelerated to a high velocity. The hot material impacts on the substrate surface and rapidly cools forming a coating. This process carried out correctly is called a "cold process" (relative to the substrate material being coated) as the substrate temperature can be kept low during processing avoiding damage, metallurgical changes and distortion to the substrate material.

The plasma gun comprises a copper anode and tungsten cathode, both of which are water cooled. Plasma gas (argon, nitrogen, hydrogen, helium) flows around the cathode and through the anode which is shaped as a constricting nozzle. The plasma is initiated by a high voltage discharge which causes localized ionization and a conductive path for a DC arc to form between cathode and anode. The resistance heating from the arc causes the gas to reach extreme temperatures, dissociate and ionize to form a plasma. The plasma exits the anode nozzle as a free or neutral plasma flame (plasma which does not carry electric current) which is quite different to the Plasma Transferred Arc coating process where the arc extends to the surface to be coated. When the plasma is stabilized ready for spraying the electric arc extends down the nozzle, instead of shorting out to the nearest edge of the anode nozzle. This stretching of the arc is due to a thermal pinch effect. Cold gas around the surface of the water cooled anode nozzle being electrically non-conductive constricts the plasma arc, raising its temperature and velocity. Powder is fed into the plasma flame most commonly via an external powder port mounted near the anode nozzle exit. The powder is so rapidly heated and accelerated that spray distances can be in the order of 25 to 150 mm.

Plasma Spray Gun in Use

The plasma spraying process is most commonly used in normal atmospheric conditions and referred as APS. Some plasma spraying is conducted in protective environments using vacuum chambers normally back filled with a protective gas at low pressure, this is referred as VPS or LPPS.

Plasma spraying has the advantage that it can spray very high melting point materials such as refractory metals like tungsten and ceramics like zirconia unlike combustion processes. Plasma sprayed coatings are generally much denser, stronger and cleaner than the other thermal spraying processes with the exception of HVOF and detonation processes. Plasma spray coatings probably account for the widest range of thermal spray coatings and applications and makes this process the most versatile. Disadvantages of the plasma spraying process are relative high cost and complexity of process.

High Velocity Oxygen Fuel Thermal Spray

Schematic Diagram of the HVOF Process

The HVOF (High Velocity Oxygen Fuel) Thermal Spray Process is basically the same as the combustion powder spray process (LVOF) except that this process has been developed to produce extremely high spray velocity. There are a number of HVOF guns which use different methods to achieve high velocity spraying. One method is basically a high pressure water cooled combustion chamber and long nozzle. Fuel (kerosene, acetylene, propylene and hydrogen) and oxygen are fed into the chamber, combustion produces a hot high pressure flame which is forced down a nozzle increasing its velocity. Powder may be fed axially into the combustion chamber under high pressure or fed through the side of laval type nozzle where the pressure is lower. Another method uses a simpler system of a high pressure combustion nozzle and air cap. Fuel gas (propane, propylene or hydrogen) and oxygen are supplied at high pressure, combustion occurs outside the nozzle but within an air cap supplied with compressed air. The compressed air pinches and accelerates the flame and acts as a coolant for the gun. Powder is fed at high pressure axially from the center of the nozzle.

 

High Velocity Oxygen Fuel Spray Gun in Use

The Coatings are very dense, strong and show low residual tensile stress or in some cases compressive stress, which enable very much thicker coatings to be applied than previously possible with the other processes.

The very high kinetic energy of particles striking the substrate surface do not require the particles to be fully molten to form high quality coatings. This is certainly an advantage for the carbide cermet type coatings and is where this process really excels.

HVOF coatings are used in applications requiring the highest density and strength not found in most other thermal spray processes. New applications, previously not suitable for thermal spray coatings are becoming viable.

Detonation Spray Process

Schematic Diagram of the Detonation Thermal Spray Process

The Detonation gun basically consists of a long water cooled barrel with inlet valves for gases and powder. Oxygen and fuel (acetylene most common) is fed into the barrel along with a charge of powder. A spark is used to ignite the gas mixture and the resulting detonation heats and accelerates the powder to supersonic velocity down the barrel. A pulse of nitrogen is used to purge the barrel after each detonation. This process is repeated many times a second. The high kinetic energy of the hot powder particles on impact with the substrate result in a build up of a very dense and strong coating.

 

Activated Combustion High-Velocity Air-Fuel Spraying Emerging Technology

Activated Combustion High-Velocity Air-Fuel Spraying (AC-HVAF) is a new industrial thermal spray technology, which incorporates the best features of both HVOF and Cold Spray processes. We have done what traditional HVAF has failed to deliver. Activated Combustion HVAF is a material deposition process in which coatings are applied by exposing a substrate to a high-velocity (600-800 m/s) jet of 10-45 um particles accelerated and heated by supersonic jet of low-temperature 'air-fuel gas' combustion products.

Like HVOF Activated Combustion HVAF process utilizes high velocity heated  particles. But spraying at temperatures (1000-1500⁰F)lower than the particles melting point, this new process avoids negative effects caused by HVOF high temperatures, (1500-2200⁰F)such as oxidation and deterioration of spray material, thus producing superb coatings of metals and carbides for a wide range of industrial needs.

Activated Combustion High-Velocity Air-Fuel process was first demonstrated in early 1990s by Dr. Viacheslav Baranovski and colleagues at the Institute of Durability and Longevity of Machines (Belorussian Academy of Science). At that time, they demonstrated a material deposition process based on the use of 20- to 50-um solid metal particles introduced into a large supersonic gas stream formed by low-temperature products of air-propane combustion. This research continued in the U.S. in early 1999.

Why Replace Chrome?

Chrome plating provides a very effective surface treatment for the reduction of wear, and in some cases corrosion. It has been in use for more than 70 years, and has proved to be a relatively cheap, effective solution. Over the past ten years HVOF coating technology has developed the point where it is widely available commercially. Equipment and powders are available from a number of suppliers, and the process is offered by aerospace-qualified job shops across North America, as well as elsewhere in the world. In general, it is found that the performance of HVOF coatings is far superior to chrome in wear, fatigue, and impact resistance, and is at least equal in corrosion resistance. Furthermore, the HVOF deposition process is faster than chrome (typically an hour or two versus 24 hours) and HVOF does not cause hydrogen embrittlement (which also eliminates embrittlement relief heat treatments). The consequent reduction of in-shop time makes many landing gear components significantly cheaper to coat by HVOF than by chrome plating. Even where HVOF is a more expensive process, its improved performance lowers the expected overhaul frequency, reducing the lifetime cost of ownership. On the basis of overall cost and performance, therefore, it makes sense to replace hard chrome with HVOF coatings.

The environmental problem with hard chrome is not with chrome itself, but with the severe environmental problems associated with the plating process. Chrome itself is essentially inert, and is in fact safely used in everyday items such as stainless steel cutlery, and even inside the body in implanted prosthetic hips and knees. The primary problem lies with the hard chrome plating process, which uses a chromic acid solution, which the plating process releases into the air in the form of a fine mist. This mist contains chromium ions in the hexavalent (Cr6+) state, which has long been known to be carcinogenic and to cause a host of other medical problems, including perforated nasal passages and skin rashes.

As a result, under the authority of the Clean Air Act, the EPA has recently promulgated new and more stringent rules to limit hexavalent chrome releases to the environment. These rules have increased the cost and complexity of hard chrome plating in many shops. Added to these rules, OSHA is expected soon to issue new regulations that will very seriously curtail the permitted levels of hexavalent chrome to which plating shop workers can be exposed. The limits, which are currently set at 100 micrograms per cubic meter, will almost certainly need to be reduced - perhaps to as low as 0.5 micrograms per cubic meter to reach the desired level of risk. The cost of reaching these levels will be very high - the National Defense Center for Environmental Excellence estimates $22 million for the first year and $46 million for each subsequent year, for the Navy alone.

While the cost of chrome plating is rising to meet stricter standards, technologies developed over the last ten years have proved to be cleaner, more effective, and sometimes cheaper than chrome plating. Their superior performance is predicted to lead to significant reductions in life-cycle cost of ownership of military systems, while improving military readiness. As a result DoD has recognized the value of reducing its reliance on chrome plating.

Aircraft Systems Being Validated

 

Chrome Replacements on Landing Gear

The major use of hard chrome in aircraft is on landing gear. A landing gear is a large hydraulic unit up to 6 feet long and 8" or so in diameter that runs inside the outer cylinder, which is attached to underside of the aircraft - essentially it is a giant version of the shock absorber in a car.  It is a high pressure gas-over-fluid system that is subject to a great deal of stress and side-loading, both on landing and during taxiing across airports with a loaded aircraft.   For carrier-based aircraft the stresses are much worse, not just because landings are harder.  During takeoff tremendous stresses are put on the landing gear by the catapult, since the catapult attaches to the nose landing gear, pulling the whole fully loaded aircraft along the flight deck to launch speed in a few seconds.  Any coating must withstand the flexure this creates on the landing gear.

A typical landing gear inner cylinder, or piston, is shown in the figure.  The inner cylinder is chrome plated, as are the journals where the wheels attach. Typically the chrome is about 0.003" (75 microns) thick.  Periodically (every 10,000 flight hours for most commercial jets, but more often for military aircraft) the landing gear must be overhauled.  On overhaul the chrome is frequently found to be worn, chipped, or otherwise damaged, and it must be replaced by stripping off the old chrome and plating on new.

HVOF Sprayed C –17 Landing Gear Post

A joint team of US Department of Defense repair depots, laboratories, and US and Canadian manufacturers of aircraft and landing gear are producing all the data necessary to replace chrome plate with HVOF WC-Co and WC-CoCr - both clean thermal spray coatings that produce no hexavalent chrome during deposition, grinding, or stripping.  In order to ensure that all of the data needed is obtained, all the stakeholders (manufacturers, Air Force single item manager for landing gear, NAVAIR, and the depot maintenance engineers) have agreed to a Joint Test Protocol, which defines the testing to be done and the pass/fail criteria (which in general are defined as performance equal to or better than hard chrome).  Tests include fatigue, wear, corrosion, hydrogen embrittlement, impact, and proper definition of the materials and deposition methods to ensure reproducibility. 

Chrome Replacement on Propeller Hubs

Although most military and passenger aircraft today are jet powered with gas turbine engines, there is still substantial use of propeller aircraft such as the C-130 Hercules transport, the E-2, and the P-3 Orion anti-submarine aircraft.  Wear in the propeller hub region in these types of aircraft is a significant source of chrome usage for NADEP Cherry Point in North Carolina and Warner Robbins ALC in Georgia.

A sub-team of the HCAT has been formed to produce all the data necessary to replace chrome plate with HVOF WC-Co and/or HVOF Tribaloy 800.

In order to ensure that all of the data needed is obtained, all the stakeholders (manufacturers, Air Force single item manager for landing gear, NAVAIR, and the depot maintenance engineers) have agreed to a Joint Test Protocol, which defines the testing to be done and the pass/fail criteria (which in general are defined as performance equal to or better than hard chrome).   Tests include fatigue, wear, corrosion, toxicity leaching, and proper definition of the materials and deposition methods to ensure reproducibility. 

Industrial Applications

 

HVOF and Detonation spray technologies for application of tungsten carbide and chrome carbide based coatings have proved to be cleaner and more effective than chrome plating. Their superior performance is predicted to lead to significant reductions in life-cycle cost of ownership in industry. However, several technical problems are holding back a wide application of these technologies:

1.Remaining porosity in sprayed coatings limits possibility to superfinish coating surface to better than Ra 1.0 microinch (0.025 micron). It is generally not a problem for hard chrome plating.

2.Consistency of coating quality is poor due to quick deterioration of spray gun hardware.

3.Low productivity of equipment results in high coating cost.

Development of Activated Combustion HVAF technology is expected to become a “break-through” in thermal spray applications for hard chrome replacement since this novel technology overcomes above-mentioned problems.

 

Optical Mirror Surface

Note: Surface finish is considered of “mirror quality” if Ra is better than 4 microinch. “Optical mirror” surface must exhibit Ra better than 0.5 microinch.

 

It is a general knowledge that HVOF tungsten carbide based coatings can not be superfinished to better than 1.0 microinch Ra. WC-20Cr-7Ni coatings, sprayed by Super-Detonation process, have been reported superfinished to 0.5-0.7 microinch. However, this is rather brittle but not hard coating compared to WC-based alternatives (WC-CoCr, WC-Co, etc.).

On the contrary, all WC-based and Cr3C2-based coatings, sprayed by AC-HVAF process, are routinely superfinished to optical mirror range. This is considered to be due to superior density of AC-HVAF coatings and absence of brittle phases usually formed due to oxidation and thermal deterioration of carbides.

 

Consistency of Coating Quality

Low temperature of air-fuel gas combustion is a primary reason for low heating of the Intelli-Jet gun parts, providing their long-term performance. Since sprayed carbides are heated substantially lower than their melting point and due to large diameter of the gun nozzle, spray particles never deposit on the nozzle wall. Thus, nozzle clogging does not limit its lifetime. As a result, the hardware performance in the AC-HVAF process is significantly better than in HVOF processes, providing an order of magnitude longer lifetime of limiting parts (nozzles, injectors, etc.). In addition, due to production rate, the AC-HVAF process needs 5-10 times shorter time for application of a coating compare to HVOF.

These factors provide a good basis for significant improvement in coating quality consistency for AC-HVAF process.

Productivity as a Key Factor in Cost Efficiency

While consuming about the same amount of spray powder as HVOF processes, the AC-HVAF technology provides 5-10 time faster application rate. This way, application cost is reduced many folds compare to HVOF and Detonation spraying. Insignificant cost of compressed air versus oxygen is another obvious factor of cost reduction. For large applications, the AC-HVAF cost efficiency becomes a breakthrough factor in using thermal spray for hard chrome replacement.

 

Oil and Gas Tooling

 

This application has long been dominated by chrome and Nickel plating to protect tooling. As the conditions under which extracting petrochemicals become more and more extreme, currently, wells are acidified to brake up pockets of oils so that they can be more easily recovered. The abrasive nature of sand, rock and mud also takes its toll on plating. Chrome and Nickel plate simply cannot hold up under these conditions. The determining factor in fully taking advantage of Thermal Spray HVOF to replace plating in this application is cost. The costs of traditional HVOF are prohibitive in all but the most extreme cases. It is likely that the success of the lower cost HVAF systems will expand the market in the oil and natural gas tooling industries.

 

Resources

 

Ace Thermal Spray Service

http://www.acespray.co.kr/

 

Gordon England

http://www.gordonengland.co.uk/

 

International Thermal Spray Association

http://www.thermalspray.org/

 

Hard Chrome Alternative Team

http://www.hcat.org/index.htm

 

Southwest United Industries

www.swunited.com

 

Halliburton  - Duncan OK

 

Stork Cellramic

http://www.cellramic.storkgroup.com/