The present invention is directed generally to tape measures and, more particularly, to a coated tape measure blade and a method of making the same.
Modern power return tape measures (or “tape rules”) typically include a coiled tape that is spring-biased towards a retracted position. A housing generally surrounds protects the tape and biasing spring and includes an opening through which a distal end of the tape extends. The distal end of the tape is pulled away from the housing during use, and when released, the spring pulls the tape back into the housing so that the tape returns to the retracted position.
The tape blades for such devices are typically formed from a metal ribbon that assumes a concavo-convex configuration when outside the housing, but that is wound into a revolute coil inside the housing with each layer of the coil having a flat cross-section. While the base material of the blade is typically metal, the surface of the blade material is rarely bare metal. Instead, the blade material is typically painted, printed with length indicia, and then coated with a polymer coating to improve abrasion resistance and/or reduce friction. This polymer coating is typically applied by passing the ribbon material over a coating roller and then through an oven to cure the coating.
Obviously, increasing the blade coating thickness has the beneficial effect of increasing the abrasion resistance; however, increasing the coating thickness increases also the space consumed by the coiled blade, thereby deleteriously increasing the overall size of the tape measure.
Separately, the conventional technique of applying the polymer coating to the blade material—using a coating roller—has proved somewhat problematic, particularly in forming a coating of a relatively uniform thickness without undesirable voids.
As such, there remains a need for alternative methods of coating a tape measure blade. While it is not required, it is preferred that the alternative methods address one or more of the problems discussed above.
The present invention is directed to a coated tape measure blade and a novel method of making the same. In one embodiment of the invention, a metallic tape blade is substantially coated with a powder and then passed through an induction unit to heat the powder and form a coating on the blade, with the blade having a concavo-convex cross-section when passing through the induction unit. In another embodiment, the metallic tape blade is substantially covered with a powder consisting essentially of nylon having a particle size of 10-20 microns or less and then passed through an induction unit to heat the blade and form a nylon coating derived from the powder thereon. In yet another embodiment, a nylon coating is applied to the metallic tape blade, with the coating having a thickness of not more than about 0.001 inches or less per side and an abrasion resistance according to ASTM D968-81 of at least 30 liters, and more preferably at least 40 liters, of sand. In still other embodiments, one or more of these aspects are combined to form a tape blade having a protective coating thereon.
As the present invention relates to a coated tape measure blade, particularly for so-called power return tape measures, a brief discussion of such devices may be helpful in understanding the present invention. As illustrated in
The tape blade 12 is typically formed from a relatively thin metal ribbon 32 shaped to form the desired concavo-convex cross-sectional shape (as shown in
The present invention relates to one or more methods of coating the tape blade 12, and preferably the painted and printed tape blade 12. As such, the discussion will assume that the tape blade 12 is painted and printed with the length indicating indicia 36 prior to the coating process, but this is not strictly required for all embodiments.
The coating process may take place at a coating process line 50, such as that shown in
For the preferred embodiments of the invention, one primary difference with the prior art coating processes lies in the use of a novel process within the coating station 60. As shown in
A powder unit 62 for use with the present invention may be formed using a number of off-the shelf components supplied by Nordson Corp. of Amherst Ohio. For instance, a triboelectric powder spray gun of part numbers 631201, 631271, 630008, and 133403 may be used in conjunction with a model 163567 hopper having a model 631401/163555 “tribo pump” and a model 631152 control unit. The powder 64 in the hopper is preferably in the form of a fluidized bed of powder that is pumped to the triboelectric powder spray gun by the tribo pump. The output of the triboelectric powder spray gun is fed to a generally cylindrical vortex tower tangent to the outer wall thereof. In the vortex tower, half the input of charged powder 64 is directed along the inside of the outer wall, and half the input is deflected by an internal deflector towards a point approximately 180° away from the input point. The vortex tower may be made from PVC, be approximately eight inches in diameter and approximately eighteen inches tall. The bottom of the vortex tower may be tilted towards an exhaust port leading to filter for pulling powder laden air out of the vortex tower for recycling to the hopper. The hopper may also be vented via a hose that lead to the vortex tower, with an input port approximately 6 inches below the input from the triboelectric powder spray gun and offset by approximately 90°. The bottom of the vortex tower should have a slit cut therein to allow for the passage of the blades 12 being processed. This slit may optionally be faced with soft bristles to help prevent unwanted escape of powder 64 from the vortex tower.
From the powder unit 62, the powdered ribbon 32 proceeds, preferably directly, to and through the fusing unit 66. While traditional coating furnaces are either electrical resistance heaters (or more rarely gas-fired ovens), the fusing unit 66 for the present invention is preferably based on the induction principle wherein a time-varying electromagnetic field is applied to the blade 12 via coil 68. In preferred embodiments, the electromagnetic field has a frequency of approximately 450 kHz. Such an electromagnetic field causes the metallic ribbon 32 to heat up very quickly and substantially uniformly. Additionally, the use of induction heating allows the blade 12 to have its “normal” concavo-convex cross-sectional shape while passing through the fusing unit 66 at a high line speed (e.g., forty to sixty feet per minute) without adverse coating effects proximate the lateral edges of the blade 12. The heat from blade 12 causes the powder 64 to fuse, forming the preferably transparent coating 34 on the painted and printed blade 12. The blade 12 then passes outside the fusing unit 66 for cooling. Note that it is preferred that the blade 12 not encounter any rollers or other guides, either while passing through the fusing unit 66, or immediately thereafter, until the coating 34 has cooled sufficiently; however, if desired, the first roller downstream from the fusing unit 66, typically disposed ten feet or more downstream, may be so-called cooling roller to additionally cool the blade 12. The final coating thickness should be on the order of 0.001 inches or less on a given side of the blade 12.
As described above, the preferred fusing unit 66 utilizes the induction heating principle. The relevant electromagnetic field is generated by passing electricity through a coil 68, with the blade 12 passing through the central opening in the coil 68. Preferably, the coil 68 has a non-circular shape, such as that shown in
It should be noted that the fusing unit 66 using the induction principle is capable of generating significant heat in the blade 12, and may even entirely melt the blade 12 if the blade 12 stops while in the fusing unit 66. Accordingly, it may be advantageous to incorporate suitable automatic systems that shutoff the coil 68 when line speed drops below a given level, such as line speed monitors and switches, etc. known in the art. In addition, other suitable safety measures known in the art may be employed, such as out-gas exhausting of the induction unit 66, flame detectors aimed at the coil 68, and the like.
One of the purposes of applying a coating 34 to the tape blade 12 is to increase the life of the blade 12. As known in the art, one useful predictor in estimating blade 12 life is the measured abrasion resistance when tested according to ASTM D968-81. The results of such testing are usually expressed as an amount of falling sand (e.g., X liters of sand) until failure is detected. Most, if not all, commercially available power return tape blades have a reading of less than twenty liters of sand using this test method. In contrast, tape blades 12 processed according to the process outlined above have a measured abrasion resistance of at least thirty liters of sand, with values of forty liters, fifty liters, or seventy-five liters of sand or more being more typical. Indeed some test results have exceed one hundred liters of sand. Thus, processing the tape blades 12 according to such a process is believed to lead to substantially improved blade life, even with relatively thin (e.g., approximately 0.001 inch thick) coatings 34.
The present invention may, of course, be carried out in other specific ways than those herein set forth without departing from the essential characteristics of the invention. Just by way of non-limiting example, the length indicating indicia 36 on the tape blade 12 may be embossed, rather than printed, without deviating from the scope of the present invention. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, and all changes coming within the meaning and equivalency range of the appended claims are intended to be embraced therein.
This application is a continuation of prior application Ser. No. 10/268,432, filed 10 Oct. 2002.
Number | Date | Country | |
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Parent | 10268432 | Oct 2002 | US |
Child | 11456327 | Jul 2006 | US |