1. Field of the Invention
The invention relates to a tool for connecting an electrical wedge connector to conductors.
2. Brief Description of Prior Developments
Electrical wedge connectors are well known in the art. One type of tool used to install an electrical wedge connector onto conductors is an installation tool which uses a powder cartridge. An example of one such tool is described in U.S. Pat. No. Re. 33,098 which is hereby incorporated by reference in its entirety.
Wedge installed connectors such as WEJTAP™ or AMPACT™ use a power booster cartridge to propel a ram to push the wedge into place. However, there is difficulty in transporting fire-arm type material across borders. There is a desire to provide an installation tool which can be used with wedge connectors, but which does not require a power booster cartridge.
In accordance with one aspect of the invention, an electrical connector installation tool is provided including a frame and a screw ram. The frame includes a front end having an anvil section adapted to contact a front end of an electrical wedge connector shell, and a rear end having a threaded aperture. The screw ram has a front end, a rear end and a middle section. The front end is adapted to contact a rear end of an electrical wedge connector wedge. The middle section includes a threaded section which is connected to the threaded aperture of the frame to allow the screw ram to be screwed into the frame and thereby move the front end of the screw ram towards the anvil section.
In accordance with another aspect of the invention, an electrical connector installation tool is provided comprising a frame and a screw ram. The frame comprises a front end having an anvil section adapted to contact a front end of an electrical wedge connector shell, and a rear end having a threaded aperture. The screw ram has a front end, a rear end and a middle section. The front end is adapted to contact a rear end of an electrical wedge connector wedge. The rear end is sized and shaped to connect to a hydraulic impact wrench for axial rotation of the screw ram by the hydraulic impact wrench. The middle section comprises a threaded section which is connected to the threaded aperture of the frame to allow the screw ram to be screwed into the frame and thereby move the front end of the screw ram towards the anvil section.
In accordance with another aspect of the invention, an electrical connector installation tool is provided comprising a frame and a screw ram. The frame comprises a front end having an anvil section adapted to contact a front end of an electrical wedge connector shell, and a rear end having a threaded aperture. The screw ram has a front end, a rear end and a middle section. The front end has a general ball shape and is adapted to contact a rear end of an electrical wedge connector wedge. The rear end has a general cross sectional polygon shape which is sized and shaped to connect to a hydraulic impact wrench for axial rotation of the screw ram by the hydraulic impact wrench. The middle section comprises a threaded section which is connected to the threaded aperture of the frame to allow the screw ram to be screwed into the frame and thereby move the front end of the screw ram towards the anvil section. The rear end of the frame comprises a section adapted to contact the hydraulic impact wrench, when the hydraulic impact wrench is attached to the rear end of the screw ram, to prevent the frame from rotating while the screw ram is rotated by the hydraulic impact wrench.
The foregoing aspects and other features of the invention are explained in the following description, taken in connection with the accompanying drawings, wherein:
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The tool 30 generally comprises the frame 20 and an adaptor or screw ram 32. The frame 20 is the same as the frame shown in
The middle section 38 has screw threads 40. The middle section 38 is screwed into the threaded aperture 29 of the support sleeve 28 such that the front end 34 faces towards the anvil section 21. When the screw ram 32 is axially rotated, the threaded engagement of the threads 40 in the threaded aperture 29 causes the screw ram 32 to longitudinally move on the support sleeve 28. Clockwise rotation of the screw ram causes the front end 34 to move towards the anvil section 21. Counterclockwise rotation of the screw ram causes the front end 34 to move away from the anvil section 21.
This adapter allows for installation of wedge installed connectors, such as WEJTAP™ or AMPACT™ without the use of a power booster cartridge to move the ram; to thereby push the wedge 16 into place in the shell 17. It also adapts to currently available frames, such as the BURNDY® red/blue or yellow WEJTAP™ frames. The hex shaped rear end allows for the adaptation of a hydraulic impact wrench which provides high torque rotational power to the unit, driving the adapter rotationally. The threads 40, engaged with the frame 20, drive the adapter 32 forward; propelling the wedge 16 into c-body shell 17 of the connector in a relatively short period of time. Although this is multiples of time longer than the current power booster installation time, it still overcomes the problems noted above with regard to shipping the tool to customers.
The benefits of this invention are that the user no longer needs to rely on a cartridge power booster to create the energy necessary to install the wedge of a wedge style connector into its mating c-body. Plus, the adapter 32 can be used with existing frames and existing hydraulic impact wrenches. This makes it easy to integrate into everyday operations without the need for additional special tooling.
Given the difficulty in transporting fire-arm type material across borders, this also facilitates the specification of wedge type connectors and this type of tool (including wrenches and frames) to foreign markets without the concern and hassle inherent in the transport of fire-arm type products.
The screw ram 32 can be provided with an optional limiter 60. The limiter 60 is movably mounted on the threads 40 of the screw ram 32. The limiter 60 can contact the rear end of the support sleeve 28 to limit the forward movement of the screw ram 32 on the support sleeve 28. The longitudinal position of the limiter 60 on the length of the screw ram 32 can be varied or adjusted by rotating the limiter 60 in the threads 40. The limiter can be a collar which could be installed to limit travel of the drive screw based upon pre-defined travel requirements for a given connector/conductor combination. Thus, the middle section 38 of the screw ram 32 could comprises indicium 62 to indicate the pre-defined travel requirements for one or more given connector/conductor combination(s). The spherical front tip of the screw ram 32 can limit contact between the tip of the drive screw and the driven wedge. This can minimize friction, and maximize rotational and linear motion of the drive screw. However, any suitable shape to push on the rear end of the wedge while the screw ram is rotated could be provided.
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The shear connector member 72 has a first end 76, an opposite second end 78, and a middle section 80. The first end 76 is sized and shaped to removably fit into the aperture 74 and form a keyed connection with the rear end 70 of the screw ram 32″. This keyed connection allows the connector member 72 to axially rotate the screw ram 32″ when the connector member 72 is axially rotated. The second end 78 is sized and shaped to be removably received in a working head of a power tool, such as a hydraulic impact wrench. The middle section 80 is sized and shaped to form a shear pin section. More specifically, when enough torque is applied the middle section can shear or break to separate the second end 78 from the first end 76.
In use, a user of the tool 30′ would insert the first end 76 into the aperture 74 and insert the second end 78 into the power tool. The user would then operate the power tool to axially rotate the connector member 72 and the screw ram 32″ together. The screw ram 32″ would longitudinally advance in the frame 20 with its front end 34 pushing the wedge 16 into the shell 17. When a predetermined torque is reached on the shear connector member 72 the middle section 80 will break. Thus, forward advancement of the wedge 16 into the shell 17 will automatically stop at a predetermined pressure.
After installation of the wedge into the shell, the used connector member 72 can be removed from the screw ram 32″ and power tool, and discarded. A new shear connector member can then be used for a subsequent new connection. One advantage with this type of system it that different shear connector members can be used with different size wedges and shells. Each different shear connector member could be adapted to shear or break at a different torque or wedge installation pressure.
With this type of alternate embodiment, a female hex or polygon shape can be made internal to the drive screw which could accept color-coded hex or polygonal inserts that would be sized and shaped to shear off at specific installation torques. These specific installation torques could match the installation torque requirements of specifically sized or color-coded wedge connectors. As an example, it is envisioned that a ‘blue’ anodized hexagonal shaped ‘shear pin’ be inserted into the drive adapter when the user is installing a ‘blue’ color coded connector, which would couple with the impact wrench, and drive the adapter forward until it reached a given installation torque, then shear off to complete the connection. The two pieces from the shear pin can then be removed from the tool and the drive adapter respectively. The color coding allows users to indicate which pin to use with which connector size; allowing the drive adapter to be re-used with new shear pins as frequently as required. The pre-defined shearing prevents over-torque, and also implies a safety means for the installer to prevent potentially harmful tool or frame rotation upon completion of the installation.
It should be understood that the foregoing description is only illustrative of the invention. Various alternatives and modifications can be devised by those skilled in the art without departing from the invention. For example, features recited in the various dependent claims could be combined with each other in any suitable combination(s). Accordingly, the invention is intended to embrace all such alternatives, modifications and variances which fall within the scope of the appended claims.
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