This application claims priority of, and is based on, the German Application No. DE 20 2012 102 562.0 filed Jul. 11, 2012.
Field of the Invention
A crimping tool is provided for crimping the tubular portion of a turned electrical contact concentrically about the bare end of an electrical conductor, including a tool body having a main first portion, and an integral coplanar second portion extending from the main body portion to define a first lever. A crimping die arrangement includes an annular stamp holder mounted opposite an opening contained in the tool body main first portion, and an annular thrust collar is mounted concentrically about the stamp holder for angular displacement between released and crimping positions, thereby to displace a plurality of stamp members radially of the stamp holder between released an crimping positions The thrust collar is angularly displaced between the released and crimping positions by a toggle link arrangement that connects a second lever both with the tool body main portion and with the thrust collar. A cascade spring force-distance arrangement adjusts the angular position of the thrust collar relative to the die arrangement when the second lever is pivoted beyond the closed position toward a maximum exertion position, which cascade spring arrangement includes a deformable resilient spring defined in the tool body main portion, and a leaf spring carried by the first lever.
Description of Related Art
Crimping tools are known in the prior art for fastening turned electrical contacts upon the bare ends of insulated wires, as shown, for example, by the German patent No. DE 10 2009 026 470 A1. In this apparatus, the lack of a force-distance adjustment device must be compensated for by the manual unlocking of a locking latch in the handle part of the tool, whereupon the crimping die, during the crimping of a turned contact upon a conductor, was blocked. Moreover, the tool must be set for the cross-sectional size of a conductor prior to the crimping operation.
The operation of the crimping tool is rather laborious because of the absence of the force-distance adjustment device. Moreover, the diameter range of the turned contacts that can be pressed with the crimping tool is limited.
However, it is desirable to have a crimping tool for turned contacts that is provided with an automatically operating force-distance adjustment so that there will be no need for the manual unlocking or adjustment of the crimping tool and, moreover, it will permit the crimping of turned contacts upon conductors with the largest possible diameter range so that the largest possible spectrum of conductor cross-sections can be provided with turned contacts with the help of a single crimping tool.
The present invention was developed therefore to provide a crimping tool for turned contacts that will avoid the abovementioned disadvantages.
Accordingly, a primary object of the invention is to provide crimping tool for crimping the tubular portion of a turned electrical contact concentrically about the bare end of an electrical conductor, including a tool body having a main first portion, and an integral coplanar second portion extending from the main body portion to define a first lever. A crimping die arrangement includes an annular stamp holder mounted opposite an opening contained in the tool body main first portion, and an annular thrust collar is mounted concentrically about the stamp holder for angular displacement between released and crimping positions, thereby to displace a plurality of stamp members radially of the stamp holder between released an crimping positions The thrust collar is angularly displaced between the released and crimping positions by a toggle link arrangement that connects a second lever both with the tool body main portion and with the thrust collar. A cascade spring force-distance arrangement adjusts the angular position of the thrust collar relative to the die arrangement when the second lever is pivoted beyond the closed position toward a maximum exertion position, which cascade spring arrangement includes a deformable resilient spring defined in the tool body main portion, and a leaf spring carried by the first lever.
According to another object, the levers are normally biased by a return spring toward the open position, and when the levers are in the closed position, a stop arrangement prevents premature opening of the crimping die.
A further object is to provide a crimping tool for turned contacts, where there is provided a force-distance adjustment arrangement in the form of a cascade spring, one of whose parts is a part of the basic tool body sheet metal pieces, and whose other part is a lever. The invention is thus based on the concept that by virtue of the advantageous spring action due to the cooperation of the springs, it is possible to supply an increased force and an increased distance for the force-distance adjustment of the crimping tool. In this way, the crimping tool can be used to crimp turned contacts on conductors with the largest possible diameter range.
A first part of the cascade spring arrangement is formed in the basic sheet metal pieces of the tool body, and is preferably defined by in each case by a slot contained in the basic sheet metal piece and that extends essentially parallel to the outer contour of the basic sheet metal piece. The terminal point of this slot is rounded to reduce the mechanical tension at the terminal point of the slot. Along its contour line, the slot advantageously runs around the associated pivot pin, and adjacent the top of the handle, emerges out of the basic sheet metal piece. This first spring preferably has a geometric configuration in the form of an arc-shaped or circular-arc segment-shaped leaf spring. To provide a worthwhile spring travel, the slot is preferably done correspondingly long and wide. The spring, thus made, is therefore outside the associated handle. By arranging the slots in opposed relation in both sheet metal pieces, a parallel alignment of both springs is obtained.
Other objects and advantages of the invention will become apparent from a study of the following specification, when viewed in the light of the accompanying drawing, in which:
By the term “turned contact” is meant those electrical contacts that are mounted on flexible conductors, whose flexibility rests on the combination of a plurality of thin conductor wires, which are combined into one conductor by means of the casing of the conductor. When such conductors, for example, are integrated into plugs, then corresponding contacts are usually employed which, on the one hand, consist of a sleeve that in the non-crimped state will receive the insulated conductor and, on the other hand, will form a massive contact, which, for example, can be integrated into a plug with multiple contacts. Such contacts, for example, are made as automatic turning part so that the concept of “turned contact” obviously provides information concerning a possible production technology used for such a contact so that such contacts are generally known to the expert by this term.
Referring first more particularly to
As shown in
According to a characterizing feature of the invention best shown in
The basic position of the crimping die assembly 104 can be changed by turning the eccentric bolt 117. In this way, one can adapt the degree of opening of the opened crimping die assembly 104 to the diameter of the turned contact 102 prior to the crimping so that an essential part of the working stroke of the crimping die assembly 104 must be carried out merely as an unproductive return stroke until crimping die assembly 104 comes into contact with the turned contact 102. The adjustment disc 121 and the flathead screw 122 fasten the eccentric pivot pin 117 in the adjusted position. Here, eccentric pivot pin 117 is used only for the initial basic calibration setting, and possibly to balance out any production or finishing tolerances. The user of the crimping tool customarily does not adjust the eccentric pivot pin 117
To make sure that the crimping die assembly 104 will always be reliably operated all the way to the final stop, the thrust strut 118 includes a gear arrangement 123 which engages the stop device 124 and thus prevents premature opening of the crimping die assembly 104. Return compression spring 125 provides for the automatic opening of crimping die assembly 104 after the crimping of the turned contact 102 has been completed.
In order to process the various cross-sections of the turned contacts 102 or conductor cross-sections in a crimping die assembly 104, a force-distance adjustment arrangement is integrated into the basic sheet metal piece 106 in the form of a cascade spring 129, which facilitates a diversion of the rear toggle lever pivot in the direction of the arrow (see
Over the area H on basic sheet metal 106 in each case, the cylindrical pin 130 is used to drive the second spring 131 of the cascade spring 129. Spring 131 is in the same plane as the thrust strut 118 that is located between the two basic sheet metal pieces 106c and 106d, and—just like thrust strut 118—has a thickness that is almost identical to the interval between the basic sheet metal pieces 106c and 106d. By means of the advantageous spring action resulting from the cooperation of springs 131, 132, an increased force and an increased distance for the force-distance adjustment device is achieved that is to be provided for the crimping tool. Here, cascade spring arrangement 129 takes care of the required residual stroke of the crimping swage 104 in the form of an elastic deformation action when crimping die assembly 104, during the crimping of a turned contact 102, has already been put upon the stop 124, although a distance must still have to be covered so that the stop 124 will release the opening of the crimping die assembly 104. Crimping tool 101 is thus automatically set for the cross-section of the turned contacts 102 that is to be crimping and the conductor cross-section. This makes it possible with only one crimping die assembly 104 to crimp conductor cross-sections of 0.08 mm2 to 6.0 mm2 step by step. Crimping tool 101 can be closed and opened automatically by skipping over the block 124.
The integration of spring 132 as a parallel-arranged leaf spring into the basic sheet metal pieces 106 facilitates a compact structure of the crimping tool 101 with simultaneous precise adjustment to the needed force-distance adjustment. Compared to other designs, they thus need less structural space with the same output. Spring 132 is made in each case in the basic sheet metal piece 106 by a slot 137 contained in the basic sheet metal piece 106c, 106d, which cut essentially runs parallel to the other contour of the basic sheet metal piece. To reduce the mechanical tension, the terminal point 138 of the slot 137 is made in a rounded configuration. Along its contour line, slot 137 runs around the pivot pin 115 so that the pivot pin 115 in each case will be in the area of the basic sheet metal piece 106c, 106d in spring 132 and otherwise in the thrust strut 118 and will emerge on the top of the handle 127 in each case out of basic sheet metal piece 106. Spring 132 thus essentially in each case has a geometric configuration in the form of an arc-shaped or circular arc-shaped leaf spring. To make a worthwhile spring travel distance, cut 137 is made accordingly long and wide. Spring 132 thus is outside handle 127.
To prevent the lifting of area H from cylinder pin 130 and basic sheet metal piece 106 under load, basic sheet metal 106, in each case in area M, has a cross-section with a high degree of stiffness. That prevents a deformation of basic sheet metal pieces 106 due to load and provides for a constantly reproducible force-distance adjustment.
While in accordance with the provisions of the Patent Statutes the preferred forms and embodiments of the invention have been illustrated and described, it will be apparent to those skilled in the art that changes may be made without deviating from the invention described above.
Number | Date | Country | Kind |
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20 2012 102 562 U | Jul 2012 | DE | national |
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101595608 | Dec 2009 | CN |
10 2005 003 617 | Jun 2006 | DE |
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102009026470 | Dec 2010 | DE |
9000098 | Jan 1990 | WO |
Number | Date | Country | |
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20140013594 A1 | Jan 2014 | US |