Patent Grant
6924249
The present invention is directed to a method and apparatus for treatment of the atmosphere, and more particularly, to a method for direct application of catalysts to a substrate via a thermal spray process and its use to treat atmospheric pollution.
Controlling atmospheric pollution is a concern of increasing importance as the levels of various atmospheric pollutants continue to increase. One primary pollutant of concern is ozone. Various components in the atmosphere can lead to the production of ozone and these compounds include those produced by internal combustion engines. Volatile organic compounds and oxides of nitrogen released into the atmosphere are two primary precursors that lead to formation of ozone in the air via photocatalysis. Most pollution control measures are directed toward removing such ozone precursors at the emission sources.
Recently, a new technology has emerged for treatment of ozone at the ground level utilizing vehicle heat exchangers. Examples of this technology can be found in U.S. Pat. Nos. 6,214,303; 6,212,882; 6,200,542; 6,190,627, and 5,204,302. These patents disclose methods for treating atmospheric pollutants by contacting the atmosphere with a catalytic composition on the surface of a substrate. The difficulty with this current technology is that getting the catalytically active compounds to adhere to the substrate requires the use of complicated binders, adhesive layers, and complex surface treatments. These procedures generally involve immersing the entire heat exchanger in a series of coating slurries to obtain a catalytically active surface. The equipment for carrying out these procedures is large and there is the additional difficulty of treating the residue. Finally, treatment of vehicle heat exchangers by these methods can tend to lead to a reduction in the heat exchange efficiency of the heat exchanger, which is undesirable.
It would be advantageous to provide a method for application of catalytically active substances to a substrate that is simple, can be incorporated easily into existing production facilities, is a one-step process, and that can be utilized to apply catalytically active substances to a variety of substrates in addition to heat exchangers.
In one embodiment, the present invention is a method of forming a catalytically active surface on a substrate for treatment of atmospheric pollution comprising the steps of: providing a feedstock of at least one catalytic metal to a thermal spray system, the thermal spray system forming a molten catalytic metal; and applying the molten catalytic metal from the thermal spray system directly onto a substrate material surface, the molten catalytic metal forming a direct bond to the substrate and forming a catalytically active layer on the substrate material surface, wherein the catalytically active layer is capable of catalyzing the conversion of at least one of ozone, hydrocarbons, or carbon monoxide to oxygen, water, and carbon dioxide, respectively, and wherein the surface and the substrate material are free from binders of the molten catalytic metal.
The present invention will now be described, by way of example, with reference to the accompanying drawings, in which:
The present invention comprises a method for formation of a catalytically active layer directly on a substrate for treatment of atmospheric pollution. In the method a thermal spray process is used to directly apply a catalytic metal to the substrate without the use of auxiliary binders or other adhesives. During application and after application, the catalytic metal forms a catalytically active layer on the substrate material surface. This catalytically active layer is capable of catalyzing the conversion of at least one of ozone, hydrocarbons, or carbon monoxide to oxygen, water, and carbon dioxide, respectively. The method can be utilized to apply the catalytically active surface to a wide variety of substrates including heat exchangers for vehicles.
Thermal spray methods are well known in the art and have been described extensively. The most common types of thermal spray systems include: flame spray; detonation gun spray; high-velocity oxyfuel; twin wire arc; and air plasma. All thermal spray systems involve heating the feedstock to a temperature above its melting point and then entraining the molten feedstock in a gas stream to accelerate it to a desired velocity. The molten entrained feedstock is then directed toward a desired substrate surface. When the feedstock and the substrate are both metals a direct metallic bond can be formed between them. In the present invention, the preferred types of thermal spray systems utilized include high-velocity oxyfuel, twin wire arc, and air plasma spray. The more preferred thermal spray systems are the high-velocity oxyfuel and air plasma spray systems. Because the air plasma thermal spray systems can achieve higher feedstock temperatures they are preferred when the feedstock utilized in the present invention comprises a metal oxide instead of the pure metal.
Regardless of the thermal spray system that is utilized in the present invention there are several general parameters that apply to any system selected. The first general parameter is to select a shortened stand-off distance between the thermal spray system applicator and the surface being coated to increase heating of the surface and the growing layer of catalytic metal thereby enhancing formation of the catalytic metal's oxide forms. The second general principle is to have the temperature of the thermal spray system be sufficiently higher than the melting temperature of the catalytic metal to additionally promote formation of metal oxides. The final general principal is to adjust the thermal spray system to increase the speed of the molten catalytic metal to enhance its adhesion to the substrate surface. In utilizing the present invention the goal is to promote the formation of metal oxides in the catalytic metal that is being applied to a surface particularly at the outer layers of the applied catalytic metal. This oxide formation enhances its ability to catalyze the beneficial reactions for cleaning of the atmosphere. Clearly, when a metal oxide is being sprayed, the goal is to ensure that it remains in this form after application.
The feedstock utilized in the present invention comprises the selected catalytic metal or metals. In the specification and the claims a catalytic metal is meant to include both the metal and any of its oxides that are either inherently catalytically active or that become catalytically active as a result of the process of the present invention. In the present invention the suitable catalytic metals comprise: manganese, copper, nickel, iron, chromium, zinc, palladium, platinum, rhodium, ruthenium, silver, gold, oxides of these metals, and mixtures thereof. When the catalytic metal is supplied as a powder, the particles used in the present invention preferably have an average nominal diameter of from 5.0 to 250.0 microns, more preferably from 15.0 to 120.0 microns, and most preferably from 25.0 to 75.0 microns. When a twin arc thermal spray system is used preferably the wires have a diameter of from 1/16 to 4/16 of an inch. These metals and their oxides are known to be catalytically active, particularly in the conversion of ozone, hydrocarbons, or carbon monoxide to oxygen, water and carbon dioxide, respectively.
In accordance with the present invention, the thermal spray system chosen is utilized to apply the molten catalytic metal to a thickness of from 10.0 to 50.0 microns onto the selected substrate material surface. The selected catalytic metal in the feedstock is heated to a temperature preferably of from 0.0 to 400.0° C. above the melting point of the feedstock to form the molten catalytic metal, more preferably it is heated to a temperature of from 0.0 to 250.0° C. above the melting point of the feedstock, and most preferably to a temperature of from 0.0 to 100.0° C. above the melting point of the feedstock. It is preferred that the molten catalytic metal be applied to the substrate material surface at an angle of from 0.0 to 80.0 degrees with the angle measured relative to a line drawn normal to the substrate material surface. More preferably, the molten catalytic metal is applied to the substrate material surface at an angle of from 0.0 to 50.0 degrees and most preferably at an angle of from 0.0 to 30.0 degrees relative to a line drawn normal to the substrate material surface. In a preferred embodiment, the stand-off distance is from 10.0 to 500.0 millimeters, more preferably a stand-off distance of from 30.0 to 100.0 millimeters, and most preferably a stand-off distance of from 30.0 to 80.0 millimeters. It is preferred that the molten catalytic metal exiting from the thermal spray system be accelerated to a velocity of from 50.0 to 900.0 meters per second, and more preferably to a velocity of from 200.0 to 900.0 meters per second, and most preferably to a velocity of from 400.0 to 600.0 meters per second. The feedstock is preferably supplied to the thermal spray system at a rate of from 0.1 to 4.0 grams per second, more preferably at a rate of from 0.4 to 2.0 grams per second, and most preferably at a rate of from 0.5 to 1.0 grams per second.
As discussed above, the thermal spray system preferably utilized in the present invention comprises either a high-velocity oxyfuel thermal spray system, a twin wire arc thermal spray system, or an air plasma thermal spray system. When an air plasma thermal spray system is utilized it is preferred that the primary gas be argon. The secondary gas is typically helium present in an amount of from 0 to 80.0% by volume, more preferably from 0.0 to 70.0% by volume, and most preferably from 0.0 to 50.0% by volume. In an air plasma thermal spray system the secondary gas may also comprise hydrogen.
One of the preferred substrates for application of the catalytic metals using the process of the present invention is to a radiator of a vehicle. The method of the present invention can be used to apply the molten catalytic metal to either the radiator fin stock or to the radiator core after assembly. The advantage of the present method is that the catalytically active layer can be applied to the radiator fin stock at a rate of several hundred feet per minute. The preferred thickness is from 10.0 to 50.0 microns, which has a minimal effect on airflow through the radiator core.
In general, it is preferred that after application the catalytically active surface be further heat treated at a temperature of from 300 to 1100° C. for a period of from 20 minutes to 2 hours in an atmosphere that includes oxygen. More preferably, the heat treatment occurs for a period of from 20 minutes to 1 hour. This post application heat annealing is not a required step to form the catalytically active layer. It is believed that during the heat treatment crystal growth occurs leading to a change in surface morphology. It is believed that following heat treatment this surface will provide a larger effective surface area for reduction of atmospheric pollutants. In addition, the heat treatment promotes enhanced oxidation of the catalytically active layer, thereby enhancing its catalytic activity.
The length and temperature of the heat treatment is determined in part by the identity of the catalytic metal used to form the catalytically active surface, for example, copper is best treated at temperatures of from 300 to 900° C., while manganese is better treated at temperatures of from 400 to 1100° C. Depending on the identity of the catalytic metal utilized it may not be beneficial to engage in a heat treatment following application of the catalytic metal by the thermal spray procedure. Testing of samples produced according to the present invention demonstrates that they are efficient in removal of ozone from air passed over the samples.
Copper metal was applied to an aluminum substrate in accordance with the present invention. A Praxair SG-100 plasma gun with a Praxair 730 anode, a Praxair 129 cathode, and a Praxair 112 gas injector was utilized. The primary gas was argon at a pressure of 40 psi (pounds per square inch), the secondary gas was helium at a pressure of 100 psi, and the carrier gas was at a pressure of 30 psi. The current was 600 Amps and the stand-off distance was 152 millimeters. The horizontal traverse speed of the applicator was 17″ per second with a vertical increment of 0.2″. Initial grit blasting was done with alumina at a size of 60 and a pressure of 40 psi. The copper utilized was SCM 200RL from X-Form at a size of +15 microns. The powder hopper wheel was rotated at 2.5 rpm with an internal powder feed and no cooling jets were utilized.
Utilizing the same plasma gun and parameters as in Example 1 above, unless noted otherwise, manganese was applied to a substrate surface according to the present invention. The primary gas utilized was argon at a pressure of 40 psi and there was no secondary gas. The system was run at a stand-off distance of 76 millimeters. The powder was Mn-104 from AEE and had a mesh size of from 100 to 325 mesh. The powder feed hopper was run at 2.3 rpm through an internal powder feed and cooling jets were utilized.
Utilizing the procedure described above in Examples 1 and 2, manganese or copper powder was applied to 8″ by 8″ flat aluminum substrates that were 0.5 millimeters thick. Each sheet was cut into strips 8″ long by 1.5″ in width. Each strip was folded in a zigzag fashion into a cylindrical form approximately ⅞″ in diameter. Each sample was heat treated at 450° C. for one hour. Two pieces of each sample were mounted in a quartz reactor tube for evaluation. A flow rate of 20.0 standard liters per minute, equivalent to a space velocity of 82,000 hour−1, or a linear velocity of 0.87 meters per second was utilized. The dry feed contained 0.22 ppm of O3 and 12.5 ppm of CO in pure air. The difference between the upstream and downstream concentrations of ozone divided by the upstream concentration was converted to a percentage and the percent removal was plotted with respect to the temperature of the system.
Manganese was applied to a radiator core utilizing an air plasma spray system. The primary gas was argon at a flow rate of 80 standard cubic feet per hour (scfh), the secondary gas was hydrogen at a flow rate of 5 scfh, and the carrier gas was argon at a flow rate of 12 scfh. The manganese powder was fed at a rate of 0.3 grams per second and the stand-off distance was 120 millimeters. The current was 450 Amps and the traverse speed was 30 centimeters per second. The system resulted in very even coating of the radiator core reaching well into the core itself.
In
Utilizing a radiator core coated as described above the efficiency of the core at removing ozone from an airstream was tested as follows. A flow rate of 10.0 standard liters per minute, which is equivalent to a space velocity of 158, 533 per hour or a linear velocity of 0.86 meters per second was passed through the radiator core. The dry feed of air contained 0.22 parts per million (ppm) of ozone and 12.5 ppm of CO in pure air. The difference between the upstream and the downstream concentration of ozone divided by the upstream concentration was converted to a percentage and called the efficiency. In
In another example a twin wire arc thermal spray system was utilized to coat a radiator core with copper. The feed stock material was 1/16″ in diameter copper wires, the voltage was 30 volts with a current of 220 Amps. The standoff distance was 76 millimeters and the atomizing gas was compressed air at a pressure of 135 psi. The traverse speed was 5″ per second. The radiator showed very even coating including deep into the interior of the fin portion of the radiator core.
The method disclosed in the present invention can be utilized to apply these catalytic metals to any substrate capable of being sprayed by a thermal spray process. Such substrates include metals, alloys, and ceramics. Thus, this invention has utilization in preparing catalytically active surfaces in a variety of components not previously possible such as metal surfaces on buildings, metal smokestacks, on billboards, on heating and cooling systems for buildings, and other surfaces exposed to the atmosphere.
The present invention finds special utilization in the application of catalytic metals to surfaces of radiators for vehicles. As discussed in the background of the invention, presently such surfaces are coated with catalytic materials through a multi-step process that includes numerous slurries and baths and, in general, it is difficult to accomplish without utilization of extraneous adhesives, resins, and protective layers.
The foregoing invention has been described in accordance with the relevant legal standards, thus the description is exemplary rather than limiting in nature. Variations and modifications to the disclosed embodiment may become apparent to those skilled in the art and do come within the scope of the invention. Accordingly, the scope of legal protection afforded this invention can only be determined by studying the following claims.
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