This application claims priority to co-pending German Patent Application No. DE 10 2011 000 464.5-34 entitled “B-Crimp-Gesenk”, filed Feb. 2, 2011.
The present invention relates to a B-shaped crimping die for a crimping tool. The crimping die is used for pressing or crimping (in the following “crimping”) a female connector, a socket, a jack, a connector, a port, a plug, a sleeve, a contact element or a connector (in the following “plug”) with at least one electrical wire or cable (in the following “cable”) located therein into a B-shape.
So-called “B-crimps” are e.g. produced with manual crimping pliers of the types CS10, CSV10, CS30, CS100 or table crimping devices CS200 of the applicant. However, it is also possible that the crimping tool is a hydraulically actuated crimping tool or any tool actuated by any type of drive.
German standard DIN EN 60352-2 (Version November 2006) describes plugs in the design of crimping sleeves. These crimping sleeves are designated for being crimped by a B-shaped crimping die. At the end of the crimping process, in a rough first approximation the plug has an outer contour in the shape of a “B”. It is possible that the vertical leg of the “B” has a convex curvature. Furthermore, it is possible that the middle horizontal leg of the “B” at least partially is not present. Accordingly, it is possible that the B-shaped crimping contour in a middle transitional region between the two curved contour regions terminates at a point. The cable is crimped within the “B” for providing a mechanical connection and/or an electrical connection between the plug and the cable.
B-shaped crimping dies are used for a so-called “cable crimping”, wherein the plug is crimped with a stripped cable, or for a so-called “insolation crimping”, wherein the plug is crimped with the insolating sleeve of a cable. To name only some examples for options of plugs to be crimped within the B-shaped crimping die, here D-sub contacts male/female, recepticals and terminals (in some cases with lateral port for a cable), cable shoes with closed crimping sleeve, universal tools for different electronic contacts like D-sub contacts or Fsh.6.3/DFK 2, HD20 contacts, HD22 contacts, Modu IV connectors, Postlock contacts, IEC contacts, MQS contacts, MCP 1.5 K contacts, MCP 2.8 K contacts; MCP 6.3/4.8 K contacts, Micro Power Quadlock 5.2, Mini UMNL, Micro Timer, Junior Power Timer, Standard Power Timer TAB 5.8, ABS contacts, SLK 2.8 contacts, MLK 1.2 contacts, LKS contacts, VKS+ contacts, SFK loop spring contacts, VEK spring contacts, flat connectors, MKR/MKS+ contacts, rsA 2+ contacts, RAM−+ contacts, VKR+ contacts, MDK 4/MDK 5 contacts, RAM machined contacts, DFK 3 contacts, FS 2.8+ contacts, AFK/AFS+ contacts, MDK 3 contacts, DFK 40 contacts, MQS contacts, MCP contacts, RSA 2+, MKR−+, MKS−+, RAM−+ contacts, VKR+ contacts, DFK 4 contacts, flat push-on receptacles and taps without insolation sleeve, 1.5/2.5 pin/socket ELA contacts (each sealed or non-sealed and/or insolated or non-insolated in any shape, design and size) are mentioned. With respect to further examples for plugs, it is referred to the advertising brochure “Tools for Professional Application” of the company WEZAG of 2010. However, it is also possible to use the B-shaped crimping dies for other types of plugs.
A basic representation and description of a B-shaped crimping plug both for a “cable crimping” and an “insulation crimping” can be taken from the Journal “Productronic”, Issue 7, 2007, pages 35-36.
For crimping a plug in a crimping die, it is necessary to apply large crimping forces. These large crimping forces are provided by manual actuation, a hydraulic drive or any other external drive. Despite of the requirement to apply large crimping forces, there are high demands and specifications for the generated outer surface and contour of the plug at the end of the crimping process.
One problem of present crimping dies is that frequently at the end of the crimping process it is not possible to remove the plug from the crimping contour of the crimping die without applying removal forces. The reason for the need for removal forces is that the plug apparently “adheres” to the crimping die. However, the application of removal forces might result in damages of the plug, the cable or of the produces mechanical or electrical connection between the plug and the cable. The adhesion between the plug and the crimping die originates in particular from the following causes:
For avoiding the above mentioned phenomena, usually lead is used as a base material for the plug or for a surface layer of the plug. Lead serves as a kind of lubricating means for easing the removal. However, the European directive EU 2002/95/EG is directed to a limitation of the use of unhealthful materials in electrical and electronical devices. This European directive aims at the avoidance of the use of heavy metal as lead. According to this European directive, since Jan. 7, 2006 work pieces as the present plugs are not allowed to contain lead.
German patent application DE 10 2009 001 949 A1 of the applicant relates to a simplification of the removal of a work piece (as a fitting for a tube connection, a cable shoe, cable end sleeves, plugs and the like) from a crimping contour of crimping pliers. In the patent application it is proposed to equip the die halves with a certain elasticity. Accordingly, at the end of the crimping process the die is elastically widened, so that the die “breathes”. Due to this breathening effect of the die it is possible that the work piece automatically detaches from the die at the end of the crimping process.
U.S. Pat. No. 5,500,999 A describes prior art wherein the plug contacts a first crimping die half defining the contour of the vertical leg of the B. The second crimping die half defines the curved parts of the B. During the crimping process, the second crimping die half is driven towards the first crimping die half. The second crimping die half comprises a bottom region defining the crimping heart. Additionally, the second crimping die half builds inclined surfaces for introducing the plug when moving into the second crimping die half. The opening angles of the inclined surfaces decrease towards the bottom region of the second crimping die half. U.S. Pat. No. 5,500,999 A complains about the problem that at the end position at the end of the crimping process due to the inclined surfaces different heights of crimped work pieces result in a gap x which is built between the two crimping die halves. The width of the gap x depends on the heights of the crimped work piece. The gap x leads to undesired burrs at the outer surface of the crimped plug. U.S. Pat. No. 5,500,999 A suggests equipping the second crimping die half with four contour parts, namely
In the tolerance region the contour parts have a distance that corresponds to the extension of the first crimping die half transverse to the crimping direction. For work pieces with different heights, the first crimping die half might be located at a plurality of different positions in the tolerance regions at the end of the crimping process without the build-up of any burrs.
Also German patent application DE 197 37 863 A1 discloses a crimping tool with a tolerance region wherein the second crimping die half comprises parallel contour parts having a distance corresponding to the width of the first crimping die half.
It is an object of the present invention to provide a B-shaped crimping die reducing the likelihood that the crimped plug with the cable crimped therein is clamped within or adheres to the crimping die. It is another object of the invention to reduce removal forces for removing the plug with the cable from the crimping die.
In the closed state of the crimping die at a transition point the crimping contour has a transition from a first crimping contour part (which is defined by a first crimping die half) to a second crimping contour part (which is defined by a second crimping die half). The present invention suggests that at the transition point an opening angle of the contour of the second crimping die half increases when seen in moving direction of the first crimping die half during the crimping process.
According to the invention, the contour of the second crimping die half comprises on both sides of the transition points flat or even guiding surfaces or straight side legs. At the beginning of the cimping process the plug is guided and deformed between these guiding surfaces or side legs. At the transition points the opening angle of the guiding surfaces or guiding side legs changes. By these measures, the invention for the first time allows for a choice of differing opening angles of the two mentioned contour parts or side legs on both sides of the transition points:
To name it in other words, the inventive crimping die removes the conflict of objectives according to the prior art: One objective of crimping dies of the prior art is to chose the opening angle of one continuous guiding surface or side leg of the contour of the second crimping die appropriate for introducing the plug into the recess built by the second crimping die half and for providing the initial deformation. The contradictuous objective for crimping dies of the prior art is to optimize the opening angle of continuous guiding surfaces or side legs of the second crimping die part for defining the contour of the plug in the closed state of the B-shaped crimping die and for easing the removal of the plug from the B-shaped crimping die.
According to the invention, the contour of the second crimping die half in front of the transition point (when seen in moving direction of the first crimping die half) comprises straight side legs with an opening angle α of 1° to 7°, in particular 3° to 6°. The contour of the second crimping die half behind the transition point (when seen in moving direction of the first crimping die part) comprises straight side legs with an opening angle β of 3° to 20°, in particular 5° to 15°. In any case, according to the invention the opening angle α is smaller than the opening angle β. To mention only one example, the opening angle α might result from α=k×β with k=0.5 (or also k=0.7 or k=0.8). However, it is also possible that k differs by ±20% from the afore mentioned values.
The present invention covers any type of contour at the transition points for the transition from the opening angle α to the opening angle β. For one embodiment of the invention, the contour of the second crimping die half is curved at the transition points. The curvature might result from the manufacturing process for shaping the recess of the second crimping die half. However, it is also possible that the curvature results from desired plastic or elastic deformations of the plug or the needs of deformation process of the plug. In case that any influence of the crimping contour in the closed state of the crimping die by the curved design of the transition points is undesired, the curved shape of the contour might be located immediately in front of the transition point such that the curved shape enters with a tangential orientation into the contour of the second crimping die half at and behind the transition point.
For another embodiment of the invention, the contour of the second crimping die half comprises a kink at the transition points. Accordingly, the opening angle of the second crimping die half in moving direction of the first crimping die half changes without a smooth transition but with a sudden increase of the opening angle. This results in a very precise shape of the crimped plug. For a lot of known crimping processes, at the transition points the B-shaped crimping die comprises tolerances in the range of 1/100 mm. These small tolerances might be deteriorated in case of shaping the transition points with smooth transitions or curvatures.
Other features and advantages of the present invention will become apparent to one with skill in the art upon examination of the following drawings and the detailed description. It is intended that all such additional features and advantages be included herein within the scope of the present invention, as defined by the claims.
The invention can be better understood with reference to the following drawings. The components in the drawings are not necessarily to scale, emphasis instead being placed upon clearly illustrating the principles of the present invention. In the drawings, like reference numerals designate corresponding parts throughout the several views.
Referring now in greater detail to the drawings,
At the beginning of the crimping process, a V-contoured plug 22 (with a curved region at the connection of the two legs of the V) or a parabolic plug 22 is positioned on the first crimping contour part 6 of the first crimping die half. A cable 23 might be built by any cable, in particular a usual bunched cable with 7 or 19 bunches or a fine-wired cable. The cable 23 is inserted in downward direction into the V build by the plug 22. With a movement of the first crimping die half 1 in moving direction 4, the first crimping die half 1 with plug 22 and cable 23 enters into the recess 3. The end regions 24, 25 of the plug 22 might comprise a larger width than the first crimping contour part 6. For this reason, the first contour legs 18, 19 have no parallel orientation but narrow towards the bottom region 14. The end regions 24, 25 when passing the second transition points 12, 13 are guided along the contour regions 15, 16. This guiding movement coincides with a rolling deformation of the plug 22: the end regions 24, 25 slide along the contour regions 15, 16 and abut at the tip of the crimping part 17. A further movement of the first crimping die half 1 in moving direction 4 has the result that the end regions 24, 25 are pressed in opposite direction to the moving direction 4 into the cable 23. In
In general, the guidance of the end regions 24, 25 is eased with an increase of the angle between the first contour legs 18, 19. However, an increase of the angle between the first contour legs 18, 19 has the result that a gap between the first crimping contour part 6 and the first contour legs 18, 19 before the end state is increased. This increase of the gap has the result that deformed material of the plug 22 enters into the gap. This effect might lead to burrs at the outer surface of the crimped plug 22 at the end of the crimping process.
An inventive B-shaped crimping die 26 will be described in the following: Generally, the inventive B-shaped crimping die 26 is build corresponding to the above described crimping die. However, the contour 27 of the second crimping die half 2 in the region of the recess 3 is built with straight first contour legs 18, 19 ending at the first transition points 7, 8. The first transition points 7, 8 correspond in the closed state of the B-shaped crimping die 26 shown in
In
The first contour legs 18, 19 comprise an opening angle α with respect to the moving direction 4 or a symmetry axis 28 of the second crimping die half 2. In
In
The inventive B-shaped crimping die 26 might be used for any tool, in particular for crimping pliers, a hydraulically actuated crimping tool or a crimping machine driven by any type of drive.
As explained in the beginning, the inventive B-shaped crimping die 26 might be used for a plug 22 of any design with at least one cable 23 in any design.
During the crimping process, with the initial movement of the first crimping die half in moving direction 4 the end regions 24, 25 of the plug 22 for the first time contact the second crimping die half 2 at contact points 44, 45 of the first contour legs 18, 19 or at the extensions 20, 21. With the further movement in moving direction 4, the end regions 24, 25 are continuously and without any interruption deformed towards each other, so transverse to the moving direction 4. The contour of the second crimping die half 2 narrows continuously and without interruption from the contact points 44, 45 towards the bottom region 14. However, according to the invention the amount of narrowing changes at the first transition points 7, 8. Any known manufacturing process might be used for manufacturing the B-shaped crimping die 26 and for shaping the contours of the die halves. To name only some examples, the B-shaped crimping die 26 might be manufactured with a wire electric discharge machining or wire eroding, a grinding process and/or a milling process. It is also possible that the described contours are stored in a computer numerical control machine used for manufacturing the contours of the B-shaped crimping die 26. The surface roughnesses of the manufactured contours should be kept as small as possible which might be provided by a polishing manufacturing process. An additional hardening process might be applied to the contours, in particular at the transition points 7, 8.
In the present invention, the second crimping die half denotes the crimping die half defining the bottom region 14 and the contour regions 15, 16 as well as the crimping die heart 17 and the second crimping contour part 9. The first crimping die half 1 denotes the crimping die half defining the first crimping contour part 6, so forming the vertical leg of the B. Accordingly, this definition is independent on further criteria. In particular, for the use of “first” and “second” crimping die half it does not matter which of these halves is moved and which half is resting.
In the present patent application, an embodiment is described wherein the first crimping die half 1 is moved towards the resting second crimping die half 2. The first crimping die half 1 enters into the recess 3 and approaches the bottom region 14. However, the inventive measures might be applied for any embodiment with a relative movement between the two crimping die halves 1, 2. In particular, the invention also covers an embodiment wherein the first crimping die half 1 is resting whereas the second crimping die half 2 is moved. The invention also covers an embodiment where both crimping die halves 1, 2 are moved towards each other.
Many variations and modifications may be made to the preferred embodiments of the invention without departing substantially from the spirit and principles of the invention. All such modifications and variations are intended to be included herein within the scope of the present invention, as defined by the following claims.
Number | Date | Country | Kind |
---|---|---|---|
10 2011 000 464 | Feb 2011 | DE | national |
Number | Name | Date | Kind |
---|---|---|---|
5500999 | Yagi et al. | Mar 1996 | A |
6098443 | Muller et al. | Aug 2000 | A |
6658725 | Liu et al. | Dec 2003 | B1 |
20100242568 | Battenfeld et al. | Sep 2010 | A1 |
Number | Date | Country |
---|---|---|
8605361 | Apr 1986 | DE |
19737863 | Mar 1999 | DE |
102009001949 | Sep 2010 | DE |
2224556 | Sep 2010 | EP |
175593 | Dec 1991 | TW |
Entry |
---|
European Directive EU 2002/95/EG. |
Wezag, Tools for Professional Application, Issue 2010, relevant pp. 13-19, 21.29, 49-59, 71-75, 105. |
Productronic, Issue 7, 2007, Was genau ist eigentlich ein Crimp? pp. 35-36. |
Kratt, Volker, Grundlagen der Crimptechnik, self-published, Issue 2005, chapter 07, p. K07/19. |
Norm DIN EN 60352-2 2006. Lötfreie Verbindungen—Teil 2: Crimpverbindungen, pp. 31-32. |
European search report in copending European application 12152053.0, mailed Apr. 26, 2012. |
Taiwanese Search Report in related, co-pending Taiwan Application No. 101103205, issued Nov. 18, 2014. |
Number | Date | Country | |
---|---|---|---|
20120192614 A1 | Aug 2012 | US |