1. Technical Field
This invention relates to the use of temperature sensors to sense the change in temperature in a mold tube of a continuous casting application as the thermal energy is removed by cooling in the water jacket. Specifically, the mounting of multiple sensors in the mold tube and protecting them from water coolant flow and volume required.
2. Description of Prior Art
Prior art devices of this type are unknown; with the current industrial use relying on a variety of make do attachment applications.
Such current use requires the application of stainless steel clad thermo sensors mounted in apertures in the mold tubes and held in place with epoxy sealants to form a water-tight seal and prevent dislodgement during operation in which cooling water is circulated about the mold tube within the fixture under high velocity to achieve the proper thermal conditions required during continuous casting.
Prior art search failed to locate any specific devices with the closest connected towards sensor retainment art in somewhat unrelated fields, see U.S. Pat. Nos. 7,157,801, 6,627,483 on thermal sensing and mounting on electrical components respectively and U.S. Publication 2007/0181336 and 2009/0107450 on automotive wiring harness and fuel line protective covers. Prior art definition directed to cooling systems for continuous steel casting machines to delineate the nature of the problem can be seen in U.S. Pat. No. 4,494,594 illustrating cooling water system needed in such continuous casting venues.
A thermocouple sensor array retainment and mounting clamp to hold and protect multiple thermocouple sensors positioned within a mold tube of a continuous casting application to monitor “cast” forming temperatures within the mold as it cools. The sensor wire harness clamp has multiple spaced sensor access apertures with an elongated deformable projection flange secured over the sensor wires by multiple retainment tabs. Mounting slots are from in the clamp to afford direct fastener attachment to the surface of the mold tube adjacent the point of access and insertion of multiple sensor wires.
Referring to
Each of the mounting tabs 17-19 has opposing angularly disposed side edges 20 and 21 with a mounting slot 22 centrally positioned therewithin. Multiple retainment flanges 23-26 extend from the side edge 13 between said respective mounting tabs 17-19 each with a fold line indicated by broken lines at L indicating the definition of the retainment flanges as folded during the assembly as will be described in greater detail hereinafter.
The main body 12 has a corresponding “body” fold line indicated by broken lines BL that extends longitudinally the length thereof midway between the respective side edges 13 and 14 defining a wire restraint flange portion 27 which in turn as folded define a wire chase 28 therewithin.
A plurality of wire access openings 29 are formed within the main body member 12 in longitudinally spaced relation to one another along the body fold line BL in transverse central alignment with the hereinbefore described retainment flanges 23-26 respectively as best seen in
End retainment flanges 30 and 31 extend from the respective end edges 15 and 16 between the corresponding body and fold over tab lines BL and L for selective engagement depending on wire assembly 11 exit position.
In use the main body member 12 is prefolded (generally) along its body fold line BL with the wire retainment flange portion 27 bent up and over the remaining body member portion being secured by the multiple retainment tabs 23-26 hereinbefore indicated by the broken bend arrows A in
It will be evident to those skilled in the art that the relative length of the body member 12 and corresponding number of mounting tabs, retainment flanges and wire access openings can vary dependent on the sensor number needed in the application venue as will be determined by operational application and described in greater detail hereinafter.
Referring now to
The harness clamp 10 which is now closed around the multiple position sensor wires 32 by the inner engagement of the multiple retainment flanges 23-26 and the corresponding end flange 31 in this application are folded over the retainment flange portion 27. The so configured harness clamp 10 is then positioned on a continuous casting mold tube body 35 that extends from a top plate 36.
The so designated mold insertion wire portions 32A of the respective sensor wires 32 extending from the harness clamp 10 are inserted into aligned mold apertures 37 in the mold tube body 35 as best seen in
Epoxy sealant indicated at 38 is in this application filled in and around the respective mold apertures 37 and their corresponding sensor wires 32A. Multiple sensor wires 32 data transfer lead portions 32B within the wire chase 28 in the stiffened cable tubing sheath 33 has a water-tight intermediate fitting 39 on the cable tubing sheath 33 which is at a distance to the assembled and secured wire harness 10 and is registerable in a support fixture 40 on the mold top plate 36 from which the mold tube body 35 extends.
A completed sensor installation at 41 allows for the positioning of the top plate 36 and mold tube body 35 into a water cooling housing 42 well known within the art as illustrated graphically in
It will thus be seen that a new and novel sensor harness clamp for continuous casting mold tubes has been illustrated and described and that the sensor clamp provides a single use universal mounting and placement retainment device for multiple thermocouple wire sensors to be used without the need for prior art stainless steel clad sensors currently in use.
It will be apparent to those skilled in the art therefore that changes and modifications may be made therein without departing from the spirit of the invention.
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