The embodiments described herein relate to crimping tools.
A crimping tool is a device that joins one or more pieces of conductors to a connector by deforming the conductor in a manner that causes the conductor to be secured to the connector. The one or more pieces of conductor may be joined together via a connector such as a compression lug. The compression lug includes a barrel with a hole at one end of the barrel for receiving a conductor such as wiring or cable. The other end of the barrel may terminate into a terminal that can be secured to a circuit or to a terminal of another compression lug. Alternatively, rather than terminating into a terminal, the other end of the barrel may include another hole for receiving another piece of wiring or cable.
A crimp tool is used to crimp the barrel of the compression lug to secure the compression lug to the conductor inserted into the compression lug. For example, a Y46 industry standard crimping tool is used to crimp the barrel of the compression lug. Generally, conventional Y46 industry standard crimp tools include a die that creates an impression on the compression lug in order to secure the compression lug to the conductor inserted into the compression lug.
To create the impression, a conventional Y46 standard crimp tool applies force to the die which is pressed on the compression lug to create a single impression on the compression lug. However, a single impression on the compression lug is insufficient to adequately secure the conductor to the compression lug. Thus, a conventional Y46 standard crimp tool must apply multiple compressions using the die to create multiple impressions on the compression lug that are sufficient to secure the conductor to the compression lug. Since multiple compressions must be applied to the compression lug, the impressions on the compression lug may be unevenly spaced due to human error in repositioning the compression lug for each compression. Accordingly, conventional Y46 standard crimp tools are inefficient and inaccurate.
The embodiments herein describe a crimp tool used to crimp metal. The crimp tool applies a single compression on a connector to create multiple impressions on the connector that are sufficient to secure the connector to conductor that is inserted into the connector. In one embodiment, the crimp tool includes a plurality of die. Each die includes a plurality of impression teeth that are used to make multiple impressions on the connector using a single compression of the plurality of die. As pressure is applied to the plurality of die, multiple impressions are formed around the connector as the plurality of die clamp around the connector thereby securing the connector to the conductor that is inserted into the connector.
The figures depict, and the detail description describes, various non-limiting embodiments for purposes of illustration only. One skilled in the art will readily recognize from the following discussion that alternative embodiments of the structures and methods illustrated herein may be employed without departing from the principles described herein.
The embodiments herein describe a crimp tool used to crimp metal. More specifically, the present disclosure is described with respect to an electrical compression lug crimp tool. However, the embodiments herein may be applicable to any other crimp tool that requires multiple impressions to secure a conductor to a connector.
In one embodiment, the crimp tool can apply a single compression to a connector to create multiple impressions on the connector that are required to secure the connector to a conductor that is inserted into the connector. Since the crimp tool can make multiple impressions on the connection through a single compression of the connector, the crimp tool can create more uniform impressions on the connector compared to conventional Y46 standard hydraulic crimp tools and are more efficient than conventional Y46 standard hydraulic crimp tools since only a single compression of the crimp tool is required to create multiple impressions.
The crimp tool includes a housing 101. The housing 101 is the frame of the crimp tool that supports the different components of the crimp tool 100 that are within the housing 101. Generally, the housing 101 is made of metal such as steel, but other metals can be used in other embodiments.
In one embodiment, the housing 101 includes multiple walls 101A, 101B, 101C, and 101D. Wall 101A is the right wall of housing 101 and wall 101B is the left wall of housing 101. Wall 101A and wall 101B may each be a ¾ inch metal plate with a length of 11⅛ inches and a width of 5¼ inches, for example. Wall 101C is the top wall of housing 101 and may be a 1 inch metal plate with a length of 6 inches and width of 5¼ inches, for example. Wall 101D is the bottom wall of housing 101 and may be a ¾ inch metal plate with a length of 10 inches and a width of 5¼ inches, for example.
As shown in
The crimp tool 100 also includes a plurality of die 103 that create impressions on a connector 107 (e.g., a compression lug) that is placed in the crimp tool 100. Specifically, the crimp tool 100 includes an upper die 103A and lower die 103B. The upper die 103A is positioned over the lower die 103B and the lower die 103B is positioned under the upper die 103A as shown in
In one embodiment, each die 103 includes a plurality of alternating rows of impression teeth and indentations. The alternating rows of impression teeth are used to form the impressions on the connector 107 positioned within the crimp tool 100 as described in detail with respect to
Referring to
In one embodiment, at least one of the upper die 103A and lower die 103B include an imprint of the die index associated with the die 103. The die index is an industry standard that specifies the specific die and metal (e.g., wire) that should be used with the connector 107. In one embodiment, the imprint on one of the upper die 103A and the lower die 103B is a protrusion that causes the logo of the die index to be imprinted upon the connector 107 when the die 103 are compressed around the connector 107. Each die may include a single imprint of the die index or multiple imprints of the die index.
Referring back to
In one embodiment, the die holders 105 are made of metal such as steel. However, the die holders 105 may be made of other types of metal in other embodiments. The die holders 105 are rectangular in shape and each die holder 105 includes a slot 115 along the length of the die holder 105. In one embodiment, a die 103 is connected to a die holder 105 within the slot 115 of the die holder 105. The slot 115 is created in each die holder 105 my milling out a portion of the die holder 105.
In one embodiment, each die holder 105 includes a spring hole at each side of the slot for placement of springs 111. For example, a first spring hole is formed to the left of the slot 115 between the ends of the die holder 105 and a second spring hole is formed to the right of the slot 115 between the ends of the die holder 105. Each spring hole is formed only partially through the thickness of the die holder 105 such as halfway through the thickness of the die holder 105.
In one embodiment, the lower die holder 105B is connected to the housing 101 via fasteners 109 such as screws and rivets. As shown in
As shown in
The upper die holder 105A is supported by a plurality of springs 111 that are placed within the spring holes formed in the upper and lower die holders 105. The plurality of springs 111 respectively support the left and right sides of the upper die holder 105B so that the upper die holder 105 is suspended above the lower die holder 105B. The springs 111 return the upper die holder 105A to the open position as shown in
For example, a first spring 111A includes a first end and a second end. The first end of the first spring 111A is placed into the first spring hole in the upper die holder 105A and the second end of the first spring 111A is placed into the first spring hole in the lower die holder 105B. Similarly, the first end of the second spring 111B is placed into the second spring hole in the upper die holder 105A and the second end of the second spring 111B is placed into the second spring hole in the lower die holder 105B.
The upper die holder 105A is secured over the springs 111 via alignment bolts 115. In one embodiment, each alignment bolt 115 is arranged through an alignment bolt hole in each corner of the upper die holder 105A and is threaded into a corresponding alignment bolt hole located in a corner of the lower die holder 105B. The alignment bolts 115 may be torqued with enough force to slightly compress the springs 111 (e.g., 10 lb/ft).
As mentioned above, the crimp tool 100 further includes a hydraulic cylinder 113 that applies force to the upper die holder 105A. Although a hydraulic cylinder is used in the crimp tool, other types of cylinders may be used such as a pneumatic cylinder. The hydraulic cylinder 113 applies force to the upper die holder 105A via a piston 401 that extends from the hydraulic cylinder 113 as shown in
Referring to
The hydraulic cylinder 113 moves the upper die holder 105A from the open position shown in
Referring to
Referring back to
In one embodiment, the positioning platform 503 is used to move the connector 107 into the correct position for crimping within the crimping tool 100. One end of the connector 107 is abutted against the positioning platform 503 and the positioning platform 503 is moved horizontally to position of the connector 107 within the crimping tool 100. The slots 505 function as a guide to restrict the movement of the positioning platform 503 along a predetermined path.
In one embodiment, the method for crimping a connector 107 includes providing 801 a crimp tool 100 that includes a plurality of die 103 where each die includes a plurality of impression teeth 201. The plurality of die 103 include an upper die 103A and a lower die 103B. The plurality of impression teeth 201 are used to create multiple impressions on the connector 107. The connector 107 is placed 803 within the crimp tool 100. Specifically, the connector 107 is placed on the lower die 103B. Pressure is applied 805 on the plurality of die 103 to compress the connector 107. That is, the hydraulic cylinder 113 applies 805 pressure to a piston 401 that presses down on the upper die 103A. As the upper die 103A is pressed downward, the impression teeth 201 of the upper die 103A contact the connector. As pressure is applied to the die, the impression teeth 201 of the upper die 103A and the lower die 103B form impressions around the connector 107. The impressions secure the connector 107 to a wire or cable that is inserted in the connector. The pressure is released 807 from the plurality of die 103 after the impressions are made around the connector 107. The connector 107 is then removed 807 from the crimp tool 100.
Although this description has been provided in the context of specific embodiments, those of skill in the art will appreciate that many alternative embodiments may be inferred from the teaching provided. Furthermore, within this written description, the particular naming of the components, capitalization of terms, the attributes, data structures, or any other structural or programming aspect is not mandatory or significant unless otherwise noted, and the mechanisms that implement the described invention or its features may have different names, formats, or protocols.
Finally, it should be noted that the language used in the specification has been principally selected for readability and instructional purposes, and may not have been selected to delineate or circumscribe the inventive subject matter. Accordingly, the disclosure is intended to be illustrative, but not limiting, of the scope of the invention.
This patent application claims the benefit of U.S. Provisional Patent Application No. 62/393,921 filed on Sep. 13, 2016, which is incorporated by reference in its entirety.
Number | Date | Country | |
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62393921 | Sep 2016 | US |