1. Field of the Invention
The present invention relates to a cable stripper apparatus for stripping insulation from an electric cable.
More specifically, the present invention relates to a cable stripper apparatus having a wire feeder and a cutter for stripping insulation from an electric cable.
2. Background Information
When a house, office or factory is rewired, enormous quantities of scrap electrical cable are generated. In the past, in an attempt to recover the valuable metal such as copper from the used cable, such scrap cable was burnt so as to remove the plastic insulation therefrom. However, with the advent and implementation of rigorous Environmental Protection Agency (EPA) and Department of Natural Resources regulations prohibiting burning of waste plastics on electrical cables, the recovery of such valuable metal has been challenging. Primarily, the EPA and Department of Natural Resources regulations introduced approximately 15 years ago were introduced in order to prevent the release into the atmosphere of harmful gases given off during burning of plastics materials such as wire insulation.
More specifically, the approximate value of stripped copper wire is 50 cents per lb. However, the value of unstripped copper wire is only approximately 16 cents per lb. The cable stripping apparatus according to the present invention provides an extremely efficient means for rapidly removing insulation from electrical cables of various gauges.
Applicants prior application which was granted as U.S. Pat. No. 6,694,853 discloses a wire stripper apparatus which includes a spacer bar which can be exchanged for another spacer bar of a different thickness so that the machine can be adapted for stripping cables having different gauges or thicknesses. However, although the arrangement described in U.S. Pat. No. 6,694,853 operates very efficiently for stripping cable, the changing of the spacer bar has been found to be inconvenient and has made it necessary to stop the machine while such spacer bar is changed to accommodate the different type of cable being stripped. The present invention provides a unique way of enabling an operator to handle different gauge wires with minimal slow down in production.
Therefore, it is a primary feature of the present invention to provide a cable stripper apparatus for stripping insulation from an electric cable that overcomes the problems associated with the prior art arrangements.
Another feature of the present invention is the provision of a cable stripper apparatus for stripping insulation from an electric cable so that insulation can be stripped from different gauge wires.
Other features and advantages of the present invention will be readily apparent to those skilled in the art by a consideration of the detailed description of a preferred embodiment of the present invention contained herein.
A cable stripper apparatus is disclosed for stripping insulation from an electric cable. The apparatus includes a framework and a driven wire feeder rotatably secured to the framework. A guide is provided for guiding the cable towards the wire feeder. The guide includes a movable spacer bar which extends towards the wire feeder. A cutter has a cutting edge which is disposed spaced and parallel to an axis of rotation of the wire feeder. The cutter is connected to the framework immediately adjacent to the wire feeder. The arrangement is such that when the cable is guided by the guide towards the wire feeder, the wire feeder, spacer bar and the cutter cooperate with each other for stripping the insulation from the cable. A cam is rotatably supported by the framework for moving the movable spacer bar relative to the framework to a required location of a plurality of locations of the movable spacer bar. The cam defines a plurality of cam faces such that when the cam is selectively rotated, a corresponding cam face of the plurality of cam faces cooperates with and moves the spacer bar to the required location of the spacer bar for guiding a particular gauge wire towards the cutter.
In a more specific embodiment of the present invention the framework includes a first member of C-shaped cross sectional configuration, the first member having a first and a second end. The framework also includes a second member of C-shaped cross sectional configuration, the second member having a first and a second extremity. The first and second members are disposed spaced and parallel relative to each other.
Additionally, the first member further includes a first bearing which is disposed between the first and second end of the first member for rotatably supporting the wire feeder. A second bearing is disposed between the first and second extremity of the second member for rotatably supporting the wire feeder so that the wire feeder is rotatably disposed between the first and second bearings.
Also, a drive is provided, the drive including an electric motor and a transmission which is disposed between the motor and the wire feeder. The arrangement is such that when the motor is connected to a source of electrical power, the motor rotates the transmission for driving the wire feeder.
In an alternative embodiment of the present invention, the drive includes a manual drive so that when the manual drive is rotated, such rotation of the manual drive rotates the wire feeder. A gearbox is disposed between the manual drive and the wire feeder so that the gearbox transmits the rotation of the manual drive to the wire feeder.
The wire feeder includes a roller of cylindrical configuration, the roller defining a plurality of teeth for engaging the insulation.
More specifically, the plurality of teeth extend in a direction outwardly from an axis of rotation of the roller.
More particularly, the direction of the teeth is offset forwardly relative to a radial direction, the offset being forwardly relative to a rotational direction of the roller.
Furthermore, a drive shaft is disposed coaxially relative to the roller so that the drive shaft is rotatably supported by the framework, the drive shaft being drivingly connected to the drive.
The guide includes a base and the spacer bar is movable relative to the base. The spacer bar extends towards the wire feeder for guiding the electric cable towards the wire feeder.
Moreover, the cutter includes a blade which is disposed adjacent to the wire feeder. The blade is secured adjacent to the guide so that when the wire feeder is being rotated and the cable is guided by the guide towards the blade, the cable is fed between the wire feeder and the blade so that the blade strips the insulation from the cable.
The cam includes a handle for rotating the cam for selecting the required location of the spacer bar. Each cam face of the plurality of cam faces is of planar configuration and spaced circumferentially relative to an adjacent cam face. Also, each cam face is spaced relative to a rotational axis of the cam.
Also, each cam face is disposed at a different distance from the rotational axis of the cam.
A movable gate cooperates with the cam such that when the cam is selectively rotated, the movable gate rides on the cam faces so that the movable gate is correspondingly moved relative to the framework by the cam faces.
Additionally, a biasing device is disposed between the framework and the movable gate for urging the movable gate towards the cam as the movable gate rides on the cam faces.
A stud slidably extends through the framework, the stud having a first and a second end. The first end of the stud is secured to the movable gate and the second end of the stud is secured to the spacer bar. The arrangement is such that when the cam is selectively rotated, a corresponding cam face of the plurality of cam faces moves the movable gate and the stud for moving the spacer bar to the required location of the spacer bar for guiding a particular gauge wire towards the cutter.
Many modifications and variations of the present invention will be readily apparent to those skilled in the art by a consideration of the detailed description contained hereinafter taken in conjunction with the annexed drawings which show a preferred embodiment of the present invention. However, such modifications and variations fall within the spirit and scope of the present invention as defined by the appended claims.
Similar reference characters refer to similar parts throughout the various views and embodiments of the drawings.
In a more specific embodiment of the present invention the framework 16 includes a first member 40 of C-shaped cross sectional configuration, the first member 40 having a first and a second end 42 and 44 respectively. The framework 16 also includes a second member 46 of C-shaped cross sectional configuration, the second member 46 having a first and a second extremity 48 and 50 respectively. The first and second members 40 and 46 are disposed spaced and parallel relative to each other.
Additionally, the first member 40 includes an upstanding extension 52 which supports a first bearing 54 which is disposed between the first and second end 42 and 44 respectively of the first member 40 for rotatably supporting the wire feeder 18. The second member 46 includes a further upstanding extension 56 which supports a second bearing 58 which is disposed between the first and second extremity 48 and 50 of the second member 46 for rotatably supporting the wire feeder 18 so that the wire feeder 18 is rotatably disposed between the first and second bearings 54 and 58 respectively.
Also, a drive generally designated 60 is provided, the drive 60 including an electric motor 62 and a transmission 64 which is disposed between the motor 62 and the wire feeder 18. The arrangement is such that when the motor 62 is connected to a source of electrical power 66, the motor 62 rotates the transmission 64 for driving the wire feeder 18.
As shown in
More particularly, the direction 76 of the teeth 72-75 is offset forwardly relative to a radial direction R, the offset being forwardly relative to a rotational direction as indicated by arrow 78 of the roller 70.
As shown in
As shown in
As shown in
As shown in
Additionally, a biasing device such as a compression spring 92 is disposed between the framework 16 and the movable gate 88 for urging the movable gate 88 towards the cam 30 as the movable gate 88 rides on the cam faces 32-37.
A stud 94 slidably extends through the framework 16.
In operation of the apparatus according to the present invention, an operator places the cable 14 to be stripped in the guide 20 with the wire feeder 18 turning so that the cable is guided between the wire feeder 18 and the cutter 24. The arrangement is such that the cutting edge 26 of the cutter 24 strips the insulation 12 from the cable 14. Additionally, if the operator needs to strip a wire having a different gauge, the operator will rotate the handle 86 and will select a cam face of the faces 32-37 so that the movable spacer bar 22 is moved to the corresponding location L1-L6 according to the type of cable being stripped. Although the present invention has been described with a cam having six faces, it will be understood by those skilled in the art that any number of faces can be provided to accommodate various cable gauges.
The present invention provides a unique apparatus for efficiently removing and stripping insulation from electric cables of different gauges and thicknesses.
The present invention is a Complete application to Provisional application U.S. Ser. No. 60/622,330 filed Oct. 26, 2004 and Provisional application U.S. Ser. No. 60/622,576 filed Oct. 27, 2004. All of the disclosure of the aforementioned Provisional applications are incorporated herein by reference.
Number | Date | Country | |
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60622330 | Oct 2004 | US | |
60622576 | Oct 2004 | US |