This disclosure relates to a system and method for removal of coatings, such as paint, from a surface using heat.
Materials such as masonry, concrete, and metal may be used in the construction of buildings, bridges, and roads, for example. These and other structures may have coatings such as paint. It can be difficult to remove coatings from these structures without damaging the underlying material structurally and/or aesthetically. Some known coating removal systems utilize mechanical stripping, such as grinding or abrasive blasting off the coating. Other known systems utilize chemicals to remove coatings.
In one exemplary embodiment, a system for coating removal comprises a frame having a platform extending within the frame. A plurality of heat lamps are mounted on the platform. The plurality of heat lamps are arranged to provide a heat density of at least 40 watts per square inch.
In another exemplary embodiment, a method of removing a coating comprises arranging a unit having a plurality of heat lamps near a surface having a coating, and applying heat to the surface with the unit. The unit provides heat to an area of at least 4 square feet at a time.
The coating removal system 10 is used to bake paint or other coatings on the building 14. The power source 18 provides power to the paint removal unit 12, which then generates large amounts of heat. The coating removal unit 12 heats the surface 15 of the building 14. Coatings on the surface 15 of the building 14 may start to break down from the heat. These coatings may then fall off, or be easily removed. The coating removal system 10 may be used to remove paint, for example. The use of heat to break down the coating may avoid the need for harsh chemicals and thousands of gallons of water. Such harsh chemicals and water are used in some known systems to chemically break down the coating.
According to some embodiments, the frame 22 may further be provided with a reflector to be set against the platform 32 on an opposite side from the support brackets 36. The reflector may be polished on a side opposite from the platform 32, and includes perforations to correspond to the perforations 34 of the platform 32. The reflector may reflect more heat towards the surface having a coating. However, in some cases, the reflector may be fouled more quickly than the platform 32. For example, off gasses from baked sealant may foul the reflector, so the reflector can be replaced on shorter intervals than the platform 32. In other examples, one side of the platform 32 may have a mirrored finish. This finish may help keep the platform 32 clean and reflect energy towards the surface to be baked.
The elements described above may be made from any of a variety of materials. In one example, each of the frame 22, tray 24, and back plate 26 may be constructed entirely or primarily of metal. The metal may be aluminum, steel, or some combination of metals or metal alloys. In another example, the frame 22, tray 24, and back plate 26 are constructed at least partially from ceramics, ceramic composites, or carbon fiber.
Turning to
The lamp 60 described above and illustrated in
Lamps 60, 160 according to certain exemplary embodiments are tube shortwave quartz infrared lamps. In further embodiments according the foregoing, the lamps 60, 160, the lamps operate at 8000 W, 3-phase 480V and may reach temperatures of up to about 4000° Fahrenheit. That is, in one example, the filament 67 in the lamps 60, 160 reaches about 4000° F., while the quartz reaches about 1200° F. The lamps 60, 160 may be 33 mm×15 mm clear quartz with a white oxide reflector coating. Each lamp 60, 160 has a crimped metal connection on ends of the lead wires for connection to the unit 12.
A plurality of lamps 60, 160 are arranged in the frame 22 to provide heat over an area. For example, the lamps 60, 160 may be arranged horizontally, supported by the support brackets 36. In another example, the lamps 60, 160 may be arranged vertically. In one example, the lamps 60, 160 are arranged to provide heat over an area between about 4 and 64 square feet. In a further embodiment, the lamps 60, 160 are arranged to provide heat over an area of about 4 ft×4 ft. The lamps 60, 160 may be arranged to provide heat over a square or rectangular area, for example. The lamps 60, 160 have about 40 inches of heated length, in one example. In one example, the lamps 60, 160 operate at about 100 watts per inch per tube, so 100 watts per inch for a single tube lamp 60 and 200 watts per inch for a double lamp 160. Thus, a 40 inch double tube lamp 60 operates at 8000 watts. The unit 12 may include 15 lamps 160. Thus, the unit 12 operates at 120 kW. The power source 18 may provide about 200 kW to the unit 12.
The disclosed unit 12 provides a much larger amount of heat over a larger area than known systems. The lamps 60, 160 are spaced to provide a large amount of heat over an area. In one example, the lamps 60, 160 are spaced such that the unit 10 provides a heat density between about 40 and 200 Watts per square inch. In a further example, the unit 10 provides a heat density between about 75 and 200 W/in2. In a further embodiment, the unit 12 provides about 144 W/in2.
Although a particular control panel 20 is shown, other arrangements may be used. In one example, the control panel 20 may include a screen to display system information to an operator. The screen may be a touchscreen to permit the operator to adjust the voltage or monitor the system. In some examples, the control panel 20 may communicate with a remote user interface to permit an operator to adjust voltage or monitor the system from a different locations, such as via a smart phone application.
The assembled unit 12 is arranged to heat the surface 15. The lamps 60 are arranged parallel to the surface 15 and oriented so the uncoated portions are directed toward the platform 32 and surface 15. The fans 46 blow air past the lamps 60 and onto the platform 32. The frame 22, fan tray 25, and back plate 26 as assembled create an enclosure, so most of the air drawn in by the fans 46 is forced through the perforations 34, which maintains the temperature of the platform 32 and helps cool the unit 12 after operation.
According to one example, the surface 15 is heated to between 500° and 925° Fahrenheit. The surface 15 is further heated convectively by air blown by the fans 46 through the perforations 34. The heating of the surface 15 bakes off the paint. The baked paint results in smoke and fumes, which are largely contained in the heated space 74 by the gasket 72. The heated space 74 is exhausted to an evacuator 76. According to one example, the evacuator 76 is connected to any of a filter, vent, pump, and fan.
Although
In some examples, a metering device, such as a potentiometer, is connected to the unit 12 to permit it to be operated at less than maximum output. For example, if the maximum output is achieved by supplying 480 volts, the unit 12 may be run at lower voltages. Running the unit 12 below maximum output may be useful to warm up before use, permit checking of the components in the unit 12, and may protect the unit 12 from unexpected voltage spikes.
In some examples, an electrical panel is used to control the power transmitted between the generator and the unit 12. The panel may be waterproof and contain waterproof components, in one example. The unit 12 and generator are connected via cables. In one example, these cables are SJ cord. The cables may 6000 volt cables, for example.
A method of using the described system 80 and unit 12 includes positioning the unit 12 near a surface having a coating and turning on the unit 12 to apply a large amount of heat to the surface. Heat is applied to the surface for a period of time to weaken the coating, then the coating is swept off the surface. In some examples, after the heat is applied, the coating is removed using compressed air. In other examples, the compressed air may include a small amount of abrasive material. In other examples, the coating is swept off using a tools such as a scraper or brush.
The disclosed system and method provides a new way to remove coatings, such as paint, from large surfaces. Some known mechanical strippers, such as grinders or vapor blasting, can damage the underlying surface. Some known chemical strippers can cause environmental problems when used over a large outdoor surface. The disclosed system and method uses heat to damage the coating for easier removal. The system provides a large quantity of heat over a large area for removal of coatings from large surfaces, such as building exteriors.
Although a combination of features is shown in the illustrated examples, not all of them need to be combined to realize the benefits of various embodiments of this disclosure. In other words, a system designed according to an embodiment of this disclosure will not necessarily include all of the features shown in any one of the Figures or all of the portions schematically shown in the Figures. Moreover, selected features of one example embodiment may be combined with selected features of other example embodiments.
The preceding description is exemplary rather than limiting in nature. Variations and modifications to the disclosed examples may become apparent to those skilled in the art that do not necessarily depart from this disclosure. The scope of legal protection given to this disclosure can only be determined by studying the following claims.
This application claims priority to U.S. Provisional Application No. 62/826,054, which was filed on Mar. 29, 2019 and is incorporated herein by reference.
Number | Date | Country | |
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62826054 | Mar 2019 | US |