Not Applicable.
Not Applicable.
The present invention relates in general to window regulators, and, more specifically, to a guide rail for receiving a window slider and having a low friction, self-cleaning coating for reducing noise, wear, and corrosion.
A window regulator for a motor vehicle is a mechanism that controls the raising, lowering and positioning of a window, such as a side door window. For a typical power window application, the regulator includes one or more rails, window clamps and sliders configured to ride on the rails and configured to secure the glass (i.e., window), a motor assembly, and cables coupling the motor to the window sliders in order to move them on the rails in a coordinated fashion. For a manual window application, a hand crank is used instead of a motor.
Conventional window regulator systems have been subject to various performance problems that lead to customer dissatisfaction. One such problem is noisy operation as the door glass is fully or partially raised or lowered. Squeaks, scrapes, or buzzing sounds often occur as the slider moves along the guide rail. These problems typically worsen over time due to washout of oils and lubricants and/or a buildup of corrosion. Another performance problem relates to blocked or intermittent movement of the door glass windows at cold temperatures when moisture becomes frozen onto the guide rails or sliders.
The present invention involves providing a particular coating which may be applied as a paint or a dry film and then cured on the guide rail that overcomes each of the foregoing problems.
In one aspect of the invention, a method is provided for manufacturing a motor vehicle window regulator. A matrix coating is applied to a metal blank, wherein the matrix coating is comprised of particles of a fluoropolymer carried in an organic polymer binder. Application may be by dipping, brushing, or spraying of the metal blank followed by curing of the matrix coating. The coated metal blank is cold-formed to the shape of a guide rail with a longitudinal track disposed along an edge of the guide rail. A window slider is mounted onto the guide rail to slide along the longitudinal track, so that the fluoropolymer particles lubricate the sliding of the window slider on the longitudinal track. The matrix coating also reduces corrosion and limits the ability of water to freeze onto the guide rail.
In particular, the matrix coating may be comprised of polytetrafluoroethylene (PTFE) with carbon black silicon carbide, bisphenol A epoxy resin, and a catalyst resin. The constituents of the coating allow cross-linking of the catalysts and appropriate flow agents to the material of the window regulator rails guide itself. The metal blank for forming the rail guide may be hot-dipped galvanized, electro-galvanized, e-coated, or phosphate pre-treated before applying the coating. The blank may include a single layer or bi-metallic joined layers. Acceptable metals include tin-free steel, alloyed steels, aluminum, and aluminum alloys.
In a coil coating process, a coil of metallic substrate material would be cleaned, rinsed, and dried before being dipped into an uncured coating mixture. The metal preferably passes through rollers to squeegee the coating to a desired thickness. Then it is dried and cured before re-rolling back into a coil and shipping to a location where it is formed into the desired guide rails. Similarly, pneumatic (e.g., spraying) and mechanical (e.g. brushed or rolled) application processes would include cleaning, drying, and curing steps to ensure good adhesion of the matrix coating to the metal blank.
Referring now to
In one preferred embodiment, an 8-micron organic polymer coating is employed, such as Xylan® 89-700 available from Whitford Corporation, Elverson, Pa. The matrix coating is comprised of particles of a fluoropolymer carried in an organic polymer binder. The fluoropolymer particles incorporated into the matrix each has a major diameter (i.e., a longest diameter) of less than about 25 microns. More preferably, each has a major diameter less than about 8 microns. In use, the particles of fluoropolymer lubricate the sliding of the window slider on the longitudinal track to provide a nearly friction-free and silent operation. Over time, the fluoropolymer particles gradually migrate out of the matrix and onto the surface thereby maintaining lubricity during the service lifetime of the guide rail. The coating improves corrosion protection of the guide rails and avoids the need for the addition of any separate lubricants. A preferred fluoropolymer for the particles is polytetrafluoroethylene (PTFE). The organic polymer binder is chosen to provide good adherence on either a galvanized or bare metal surface of the guide rail, and may be comprised of silicon carbide or bisphenol A epoxy resin, for example.
In order to achieve efficient and cost effective manufacturing of the guide rails, the matrix coating of the present invention is applied to a metal blank before being shaped to the configuration of a guide rail.
Referring to
Spool 28 containing the coated steel coil is moved to a forming process as shown in
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Entry |
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The Whitford Engineering Design Guide, Jan. 2006, pp. 1-41. |
Number | Date | Country | |
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20140157677 A1 | Jun 2014 | US |