Patent Grant
6875472
Environmental concerns have led to an attempted reduction of pollutants from a multitude of sources. Manufacturing facilities, have been required to operate under increasingly stringent emissions guidelines. These emissions guidelines require, in part, a reduction of volatile organic compound (VOC) emissions.
In a manufacturing environment, VOC's have a wide variety of uses. For example, certain VOC's have been commonly employed for the purpose of cleaning and preparing various plastic components for receiving a material coating, such as paint. More specifically, such VOC's are particularly useful for cleaning and preparing thermoplastic polyolefin (TPO) components for coating with a primer or paint product. Not only are such VOC's effective for the removal of grease and other contaminants which may reside on these components, they also act on the surface of the TPO to promote adhesion with the forthcoming primer or paint coating.
In an attempt to reduce emissions, it has become essential to drastically reduce or eliminate the use of VOC's. For similar reasons, most automobile manufacturers also now employ a water-based paint and/or primer rather than traditional solvent-based products.
New plastic formulations have been developed which may be cleaned via non-VOC methods, and which are better able to bond with water-based paint and/or primer. However, TPO exhibits inherently poor wettability—meaning that it tends to repel moisture. Without the use of trichloroethylene or similar materials to prepare the surface, providing adequate paint adhesion is of great concern. For this reason, manufacturers utilizing a water-based cleaning system and water-based paint, typically provide the TPO components with a primer coat prior to the final paint or color coat.
Unfortunately, primer coating is a costly process. One reason is that a large portion of the sprayed primer is typically lost rather than deposited on the component. Additionally, once the components have received a primer coat, it is generally necessary to cycle them through an oven to allow the primer to fully dry. Therefore, it is desirous to develop a system and method that will allow a paint coating to be applied directly to the surface of a TPO component, without the need to first apply a coat of primer.
The present invention satisfies this need. The system and method of the present invention applies a water-based adhesion promoter to each TPO component. The adhesion promoter application preferably occurs after the component has undergone a cleaning process. After the adhesion promoter is applied and dried, a thin layer will remain on the surface of the TPO component. This thin layer of adhesion promoter is sufficient to provide the necessary adhesion between the component and the forthcoming paint coat.
The adhesion promoter application system of the present invention may monitor a variety of parameters during operation, including, for example: line speed of the component; temperature of the component; temperature of the adhesion promoter; adhesion promoter nozzle distance and angle; adhesion promoter flow rate; nozzle spray pattern; setting zone time, temperature and relative humidity; and pre-oven and oven time, temperature and relative humidity. The adhesion promoter application system of the present invention may also be adapted to distinguish when a part is present within the system and to provide periodic water flushing in order to prevent adhesion promoter build-up.
Therefore, the adhesion promoter application system of the present invention allows a paint coat to be applied to the surface of a TPO component without the need to first apply a primer coat. As such, the present invention may provide a reduction in material, equipment and labor costs, as well as an increase in production capacity.
In addition to the novel features and advantages mentioned above, other objects and advantages of the present invention will be readily apparent from the following descriptions of the drawings and embodiments, wherein:
A schematic representation of various components of one embodiment of the adhesion promoter application system 10 of the present invention can be seen in
The treatment enclosure 15 is preferably closed at its entrance by a first air seal 20, and at its exit by a second air seal 25. A fan 30 may provide the air supply necessary to maintain the air seals 20, 25. The TPO elements are preferably cooled prior to entering the treatment enclosure 15, thus, the first air seal 20 helps to prevent cool air from entering the treatment enclosure. A pre-oven is preferably connected to the exit portion of the treatment enclosure 15. Similar in function to the first air seal 20, the second air seal 25 helps to prevent hot air from the pre-oven from entering the treatment enclosure 15. An air temperature and humidity conditioner 35 is preferably provided to maintain the atmospheric conditions within the treatment enclosure 15. A chiller 40 and a boiler 45 are provided to supply cooled and heated water, respectively, to the air temperature and humidity conditioner 35.
A supply tank 50 is preferably utilized to maintain a source of an adhesion promoter for use by the system 10. A stock of adhesion promoter 55 and a supply of de-ionized water 60 are preferably in metered communication with the supply tank 50. The adhesion promoter stock 55 is further metered and controlled by a surface tension meter 65. The surface tension meter 65 is adapted to analyze a wet sample of adhesion promoter, and thereby control the amount of adhesion promoter and solvent that is supplied to the supply tank 50. A re-circulation pump 70 is preferably used to re-circulate the adhesion promoter through an ultra-filtration module 75 for removing particulate contamination.
The adhesion promoter in the supply tank 50 is preferably supplied to a gravity tank 80 by means of a supply pump 85. The adhesion promoter preferably passes through a supply filter 90, and also passes through a heat exchanger 95 on its way to the gravity tank 80. The heat exchanger 95 operates to adjust the temperature of the adhesion promoter traveling to the gravity tank 80. Preferably, the temperature of the adhesion promoter in the gravity tank is maintained at between about 20-25° C. The chiller 40 and boiler 45 also supply cooled and heated water, respectively, to the heat exchanger 95.
From the gravity tank 80, the adhesion promoter is preferably directed to a multitude of nozzles 100 within the treatment enclosure 15 for application to the passing TPO elements. The temperature of the adhesion promoter may be monitored within the gravity tank 80 and the flow rate may be monitored at the nozzle 100 outlets to ensure proper application to the TPO elements. Operation and monitoring of the system 10 may be conducted via an operator/electrical panel 105.
Alternate embodiments may also be possible. For example, the stock of adhesion promoter 55 and supply of de-ionized water 60 may be supplied directly to the gravity tank 80 or directly to the nozzles 100. Alternatively, the supply tank 50 may be used without the gravity tank 80, whereby the adhesion promoter may be supplied directly from the supply tank to the nozzles 100.
An overview of the TPO element coating process 150 of the present invention can be seen by reference to FIG. 3. In the present invention the TPO elements, traveling in the direction of the arrows, enter a pretreatment enclosure 155. Within the pretreatment enclosure 155, the TPO elements preferably undergo a washing/degreasing process and are then subjected to application of the adhesion promoter in a treatment section of the enclosure. Because the adhesion promoter allows a base coat to be applied directly to the adhesion promoter-treated surface of the TPO elements, the need for a primer booth and primer oven is obviated. Therefore, as shown in
Another advantage to the process of the present invention is depicted in FIG. 3. Because no primer booth or primer oven is required, at least one additional paint booth 170 and paint oven 175 may be available for receiving adhesion promoter-treated parts. The additional paint booth 170 and paint oven 175 may be created by converting a pre-existing primer booth and primer oven, for example. Thus, the adhesion promoter application system and process of the present invention may also serve to double the production capacity of the TPO element paint process.
A graphical representation of the various stages of an embodiment of the adhesion promoter application process 200 of the present invention can be seen in FIG. 4. For purposes of clarity, the enclosure portion of the system is represented as transparent. It should also be noted that although a carrier 225 is shown in
The TPO element 210, represented in this embodiment as an automobile bumper fascia, can be seen near a cooling portion 215 of a pretreatment enclosure 220. As represented in this position, the TPO element 210 has already been subjected to a washing/degreasing operation in a more forward portion (not shown) of the pretreatment enclosure 220.
Because the temperature of the TPO element 210 has likely become elevated during the washing/degreasing operation, the TPO element is transported in the direction of the arrows by the carrier 225, and through a cooling device 230. For purposes of illustration, the cooling device 230 may be a series of nozzles spraying cooled, de-ionized water, as represented here, but other embodiments are also possible that can produce the desired effect. The cooling device 230 preferably reduces the temperature of the TPO element 210 to approximately that of the adhesion promoter application section 235 of the pretreatment enclosure 220. Cooling of the TPO element 210 is desirable to prevent heat transfer from the TPO element to the atmosphere within the adhesion promoter application section 235 of the pretreatment enclosure 220.
A first air seal 240, preferably created by a fan 30 (FIG. 1), assists in preventing the atmosphere of the cooling portion 215 of the pretreatment enclosure 220 from influencing the atmosphere within the adhesion promoter application section 235. The temperature of the first air seal 240 is preferably maintained at approximately the desired interior temperature of the adhesion promoter application section 235 of the pretreatment enclosure 220.
The TPO element 210 and carrier 225 pass through the first air seal 240 and into the adhesion promoter application section 235 of the pretreatment enclosure 220. A second air seal 245 separates the adhesion promoter application section 235 of the pretreatment enclosure 220 from a pre-oven 265. At a point preferably nearer the first air seal 240, an application portion 250 (
The remaining segment of the adhesion promoter application section 235 of the pretreatment enclosure 220 located between the application portion 250 and the second air seal 245 is used as a setting zone 260. The setting zone 260 allows at least a portion of the adhesion promoter to flash off of the TPO element 210 before entering the pre-oven 265. Preferably, the adhesion promoter application section 235 of the pretreatment enclosure 220 is maintained at a temperature of between about 20-25° C. and a relative humidity of between approximately 40-70%.
Upon exiting the adhesion promoter application section 235 of the pretreatment enclosure 220 through the second air seal 245, the TPO element 210 preferably enters a pre-oven 265, where the temperature of the TPO element and the remaining adhesion promoter is elevated prior to entering a drying oven 270. The temperature may vary from between approximately 25-65° C., and the relative humidity may vary from between about 15-60% depending on the location of the TPO element 210 within the pre-oven 265.
The adhesion promoter remaining on the TPO element 210 is preferably further dried in the drying oven 270 prior to entering a paint booth 160, 170 (FIG. 3). The temperature may vary from between approximately 45-95° C., and the relative humidity may vary from between about 5-25% depending on the location of the TPO element 210 within the drying oven 270.
An enlarged, frontal view of an embodiment of the application portion 300 of the adhesion promoter application system is shown in FIG. 5. Multiple TPO elements 210 can be seen to be placed in communication with a supply of an emitted adhesion promoter 310 by the carrier 225. In this embodiment, the adhesion promoter 310 is supplied, preferably via a gravity tank (not shown), to a main and secondary supply header 315, 320. The use of a gravity tank helps to prevent foaming of the adhesion promoter 310 as it contacts the TPO elements 210, by reducing the amount of air trapped therein. It has been found that excessive foaming may lead to defects, such as streaks, runs, and sags in the layer of adhesion promoter deposited on the TPO elements 210.
Each of the main and secondary supply headers 315, 320 are shown to have multiple nozzles 325, 330 for distributing the adhesion promoter 310 upon the TPO elements 210 passing underneath. Although the number of nozzles 325, 330 may vary, good results have been achieved by using between about 15-30 total nozzles.
The nozzles may be of differing configuration to allow for various adhesion promoter 310 distribution patterns. Various shapes, such as a stream 335 or a fan pattern 340, for example, may be employed to most appropriately distribute the adhesion promoter 310 about the TPO components 210 without causing defects.
Each of the nozzles 325, 330 preferably also possesses its own flow control device (not shown). The flow control device may be a manual valve, or an electronic solenoid operated valve, for example. The use of a flow control device is preferred, as it has been found that the flow rate of the adhesion promoter 310 can affect the quality of the final adhesion promoter layer that will remain on each of the TPO components 210. Satisfactory results have been achieved using an adhesion promoter flow rate of between approximately 0.5-2.5 liters per minute, and in one example embodiment, the adhesion promoter flow rate is approximately 1.5 liters per minute.
As can be seen, the nozzles 325, 330 are preferably angled in the direction of travel of the TPO elements 210, which direction is indicated by the arrow. Delivering the adhesion promoter 310 through an angled nozzle 325, 330 appears to reduce the force of impact on the TPO element 210 by the adhesion promoter, thereby reducing foaming and subsequent adhesion promoter layer defects. Although the optimum angle φ of the nozzles may vary depending on the configuration of the TPO element 210 to which the adhesion promoter 310 is to be applied, good results have been obtained utilizing a nozzle angle φ of between about 10-45 degrees relative to vertical. However, based upon factors such as TPO element configuration, TPO element linear velocity, adhesion promoter flow rate, and nozzle to element distance, for example, lesser or greater nozzle angles may also give satisfactory results.
As also shown in
Now referring to
A variety of nozzle diameters 390 may be employed to adequately expel the adhesion promoter 310. However, for the embodiments illustrated in
It has been discovered through experimentation that the distance D between the nozzles 325, 330 and the surface of the TPO element 210 also may have bearing on the quality of the adhesion promoter layer that will be deposited thereon. As with flow rate and angle of impact, it appears that the distance D between the nozzles 325, 330 and the surface of the TPO element 210 affects the amount of splashing and foaming of the adhesion promoter 310 that will occur. Depending on adhesion promoter flow rate, linear speed of the TPO elements 210, and TPO element configuration, a distance D of between approximately 0.25-14 inches has yielded acceptable results. For the embodiments shown in
The operating procedure of a particular embodiment of the present invention can be seen in the diagram of
Next, electrical power is applied to a pump for supplying the adhesion promoter 460. Upon activation of the adhesion promoter pump 460, an adhesion promoter tank temperature sensor 465, which is in communication with both a modulating valve for the hot water return from the heat exchanger 470 and a modulating valve for the chilled water return from the heat exchanger 475, operates to maintain the desired temperature of the adhesion promoter. Activation of the adhesion promoter pump 460 also triggers a check of adhesion promoter on/off flow control valves 480, and part-gap detection photo sensors 485, which evaluate the position of the adhesion promoter application nozzles in relation to the TPO elements to be treated. The adhesion promoter on/off flow control valves 480 are also interconnected to a solenoid valve for de-ionized water nozzle purging 490, which periodically provides de-ionized water to the nozzles to prevent the build-up of adhesion promoter.
A filtration pump 495 and a de-ionized water pump 500 are then turned on. The energizing of the de-ionized water pump 500 activates a de-ionized water temperature sensor 505. The de-ionized water temperature sensor 505 is in communication with the modulating valve for the chilled water return from the heat exchanger 510, which allows the temperature sensor 505 to control the temperature of the de-ionized water supply that may be used, among other things, to rinse and cool the TPO elements prior to application of the adhesion promoter.
An adhesion promoter tank pH sensor is next activated 515, along with an adhesion promoter tank electrical conductivity sensor 520. The pH sensor 515 and the conductivity sensor 520 allow the properties of the adhesion promoter to be monitored.
The scope of the invention is not to be considered limited by the above disclosure, and modifications are possible without departing from the spirit of the invention as evidenced by the following claims:
This application is a continuation of application Ser. No. 09/577,776, filed May 24, 2000 now abandoned, for Adhesion Promoter Application System and Process, which is expressly incorporated herein by reference.
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| Number | Date | Country |
|---|---|---|
| 0 517 471 | Dec 1992 | EP |
| WO 9731694 | Sep 1997 | WO |
| WO 9747678 | Dec 1997 | WO |
| Number | Date | Country | |
|---|---|---|---|
| 20040071886 A1 | Apr 2004 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | 09577776 | May 2000 | US |
| Child | 10675168 | US |
