CABLE ASSEMBLY WITH MALE CONNECTOR WITH LOW PROFILE

专利摘要:
The assembly (250) includes a connector housing (252) fully insertable into a female connector of an electronic device (100), with a back surface that conforms to an exterior shape of the device. A cable (254) is coupled to the connector housing, with conductive tracks that match and are electrically coupled to pins disposed in the connector housing. A connector socket (256) is mechanically coupled to the connector housing by the cable, the connector socket having a plurality of connection pads electrically coupled to respective connection pads of the plurality of conductive tracks.
公开号:FR3066328A1
申请号:FR1800436
申请日:2018-05-09
公开日:2018-11-16
发明作者:Cesar Lozano Villareal；Dominic E. Dolci；Victoria A. Spielmann；Ricardo A. Mariano；Alexander M. Kwan；James G. Smeenge；Daniele De luliis
申请人:Apple Inc；
IPC主号:

专利说明:

The present invention relates to a connector. The present invention relates more particularly to a low profile male connector capable of being fully inserted into an electronic device and profiled to match an external surface of the electronic device.
There are many types of electrical connectors for interconnecting electronic devices in the state of the art. Such connectors generally include a female connector (receptacle) and a male connector (plug). The male connector can engage the female connector to make an electrical connection between pin-shaped electrodes in each connector.
The reduction in size of electronic devices is reflected in a marked desire to also reduce the size of electrical connectors. However, reducing the size of the electrical connectors is a source of many problems. For example, reducing the size of an electrical connector requires a corresponding reduction in size of the pin-shaped electrodes disposed in the connector. Reducing the size of the electrodes tends to increase the stresses and forces applied to the electrodes when they are engaged in a receiver connector. This has the effect of reducing the integrity and efficiency of the connector over time.
In addition, electrical connectors are generally coupled to, or part of, a part of a cable assembly. Cable assemblies and electrical connectors of this type often protrude and protrude from electronic devices in a disorganized manner. As a result, the electrical connectors and the cable assemblies attached to them are often troublesome and unsightly.
The embodiments of the present invention generally relate to electrical connectors, cable assemblies and connector pins. An electrical connector may include pin-shaped electrodes and be part of a cable assembly while being capable of being fully inserted into an electronic device and shaped to match an exterior surface of the electronic device.
In some embodiments, a cable assembly includes a connector housing, a cable, and a connector base. Different characteristics of the cable assembly can, alone or in combination with one another, fill all or part of the shortcomings of the prior art described above.
For example, the connector housing may have a rear surface which is at least curved or inclined relative to a front surface of the connector housing, so as to conform to an outline of an exterior surface of an electronic device. It is thus advantageously possible to reduce the size and the visual projection of the connector housing. In another example, the connector housing may have a depth and an interior cavity designed to accommodate one or more pins. The pins may each include a connection portion and the connection portions of adjacent pin pairs may be staggered relative to each other. In this way, mutual annoyance between adjacent pins can advantageously be reduced. In yet another example, the pin connection portions may extend substantially perpendicular to a rear surface of the connector housing. In this way, the integrity of the pins and the integrity of a coupling between the pins and the cable can advantageously be increased.
In other embodiments, a pin is provided to establish an electrical connection with a receiving pin. Different characteristics of the spindle can, alone or in combination with one another, fill all or part of the shortcomings described above in the prior art.
For example, the pin may include a base, an elongated body, and an engagement portion. The base may include a cutout to increase the length of the elongated body. In this way, the forces applied and the stresses inside the spindle can advantageously be reduced. In another example, the elongated body may include an end stop protruding from an upper surface of the elongated body. The end stop can distribute a force applied to the elongated body when the engagement part is engaged in the take-up spindle. This advantageously makes it possible to reduce the forces applied and the stresses inside the spindle. 0
For a better understanding of the nature and advantages of the embodiments of the present invention, reference is made to the detailed description below and to the accompanying drawings. Other aspects, objects and advantages of the invention appear from the drawings and the detailed description which follows.
Figure IA shows a perspective view of an electronic device which can be part of a digital signage system according to an embodiment of the present invention.
Figure IB shows a side view of the electronic device shown in Figure IA.
FIG. 2 represents a digital signage system comprising a cable assembly according to an embodiment of the present invention.
FIG. 3A represents a perspective view of a docking station intended to receive a cable assembly according to an embodiment of the present invention.
Figure 3B shows a top view of the docking station shown in Figure 3A.
Figure 3C shows a rear view of the docking station shown in Figure 3A.
Figure 3D shows a side view of the docking station shown in Figure 3A.
Figure 3E shows a bottom view of the docking station shown in Figure 3A.
Figure 4 shows a cable assembly according to an embodiment of the present invention.
Figure 5A is a front perspective view of a male electrical connector according to an embodiment of the present invention.
FIG. 5B is a perspective view from behind of a male electrical connector according to an embodiment of the present invention.
FIG. 5C is a perspective view of a male electrical connector coupled to a cable according to an embodiment of the present invention.
Figure 6A is a side view of a pin disposed in a male electrical connector according to an embodiment of the present invention.
Figure 6B is a side view of a pin disposed in a male electrical connector engaged in a receiving pin according to an embodiment of the present invention.
Figure 7A is a side view of a spindle according to a first embodiment of the present invention.
Figure 7B is a side view of a spindle according to a second embodiment of the present invention. 0
Embodiments of the invention are discussed below with reference to Figures IA to 7B. However, those skilled in the art will readily understand that the detailed description given below with respect to these figures has only an explanatory purpose since the embodiments of the invention go beyond these limited embodiments .
FIG. 1A represents a perspective view of an electronic device 100 which can be part of a digital signage system according to an embodiment of the present invention. According to this embodiment, the electronic device 100 is a tablet computer. The electronic device 100 may be an iPad as manufactured by Apple, Inc. in Cupertino, CA, USA; a Toshiba Tablet as manufactured by Toshiba Corp. in Tokyo, Japan; a Z-Pad as manufactured by ZTE Corp. in Shenzhen, China; an EEE Pad as manufactured by Asus in Taipei, Taiwan; a Dell Streak as manufactured by Dell in Austin, TX, USA; a Samsung Galaxy as manufactured by Samsung Group in Seoul, South Korea, etc. (these names being registered trademarks) According to other embodiments of the present invention, the electronic device 100 is not a tablet computer. Indeed, the electronic device 100 can be any portable electronic device provided with a screen. For example, the electronic device can be a cell phone, personal digital assistant (PDA), media player (e.g. music or video player), camera, game console, laptop, netbook, a booklet, a slate, a convertible laptop, etc.
The electronic device 100 includes an upper surface 102, a rear surface 104 and lateral surfaces 106. According to one embodiment, the upper surface 102 is a digital display. According to another embodiment, the upper surface 102 is a digital display incorporating a touch screen functionality, thus allowing a user to operate the electronic device 100 by interacting with the screen.
The electronic device 100 can also include different buttons on different surfaces to activate different functionalities of the device. For example, the electronic device 100 may include a multifunction button 108 disposed on the upper surface 102, a volume control button 110 on a side surface 106, a volume mute button 112 on a side surface 106, a stop-on button (not shown) on the rear surface 104, etc. The electronic device 100 can also include, on different surfaces, different mechanical interfaces for interfacing with other electronic devices and / or accessories. For example, the electronic device 100 may include a female connector 114 on a side surface 106 for connection to other electronic devices using a cable from a cable assembly, an audio jack (not shown) on a surface side 106 for connecting speakers, etc. The electronic device 100 may also include other elements creating projections or recesses on or in the surfaces of the electronic device 100, such as cameras, microphones, speakers, antennas, etc.
Figure IB shows a side view of the electronic device shown in Figure IA. This view makes it possible to see that the rear surface 104 is curved in the form of a bowl. In some embodiments, the rear surface 104 includes curved surfaces 104a and a substantially planar surface 104b. In other embodiments, the entire rear surface 104 is curved, so that there are substantially no planar surfaces in the rear surface 104.
The rear surface 104 may project from a predetermined depth relative to the side surfaces 106. For example, the rear surface 104 may project from a depth of about 0.5 inches (12.7 mm) from to the side surfaces 106. In another example, the rear surface 104 may project from a depth of between about 0.05 inch and 0.25 inch (1.27 and 6.35 mm) relative to the side surfaces 106 In yet another example, the rear surface 104 may project from a depth greater than 0.25 inch (6.35 mm) or less than 0.05 inch (1.27 mm) from the side surfaces 106 .
The side surfaces 106 may project from a predetermined depth relative to the top surface 102. For example, the side surfaces 106 may project from a depth of about 0.15 inch (3.81 mm) by relative to the upper surface 102. In another example, the side surfaces 106 may project from a depth of between about 0.05 inch and 0.25 inch (1.27 and 6.35 mm) from the upper surface 102. In yet another example, the lateral surfaces 106 may protrude more than 0.25 inch (6.35 mm) deep or less than 0.05 inch (1.27 mm) from the upper surface 102.
In some embodiments, the side surfaces 106 may be arranged substantially perpendicular to the top surface 102. In other embodiments, the side surfaces 106 may be arranged at an angle of less than ninety degrees relative to the upper surface 102, so that the side surfaces 106 are directed inward towards a center of the electronic device 100. In some embodiments, the side surfaces 106 may be substantially planar while, in in other embodiments, the side surfaces 106 can be curved inward. In some embodiments, the side surfaces 106 are arranged to be continuous with the rear surface 106; for example, the side surfaces 106 may be mechanically coupled with the rear surface 104, so that there is no visible discontinuity between the side surfaces 106 and the rear surface 104. In other embodiments, there there are no side surfaces 106; for example, the rear surface 104 can project directly from the upper surface 102. In certain embodiments, the lateral surfaces 106 have angles which are substantially identical with respect to each other; for example, all of the side surfaces 106 may be substantially perpendicular to the top surface 102. In other embodiments, the side surfaces 106 have different angles to each other; for example, one of the lateral surfaces 106 can be substantially perpendicular to the upper surface 102, while another of the lateral surfaces 106 can be arranged at an angle of less than ninety degrees relative to the upper surface 102.
FIG. 2 represents a digital signage system 200 comprising a cable assembly 250 according to an embodiment of the present invention. The digital signage system 200 comprises an electronic device 100 such as that described with reference to FIGS. IA and IB, a docking station 210 allowing the mounting of the electronic device 100 and the cable assembly 250.
The docking station 210 comprises a body 212 intended to support the electronic device 100. The docking station 210 will be described in more detail with reference to FIGS. 3A to 3E. In general, however, the body 212 includes an upper surface having a recessed region formed therein. The hollowed out region can be shaped to receive the electronic device 100 so that, when the electronic device 100 is positioned inside the hollowed out region, the rear surface 104 of the electronic device 100 fits entirely inside the hollowed out region while the upper surface 102 of the electronic device 100 is substantially level with a part of the upper surface of the body 212 which surrounds the hollowed out region. As previously mentioned, in some embodiments, the electronic device 100 may include side surfaces 106. Accordingly, in some embodiments, the recessed region of the body 212 can be shaped to receive the electronic device 100 so that when the electronic device 100 is positioned inside the recessed region, one, several or all of the lateral surfaces 106 of the electronic device 100 are contiguous with a surface of the recessed region. The cable assembly 250 may include a connector housing 252 sized for insertion into the female connector 114 of the electronic device 100. The connector housing 252 may be designed to accommodate one or more pins which, when the connector housing 252 is engaged with the electronic device 100, establish electrical contact with one or more pins disposed inside the female connector 114. The connector housing 252 will be described in more detail with reference to Figures 5A to 6B. In one embodiment, the connector housing 252 can be designed to fully fit inside the female connector 114 and to have a rear surface that matches the shape and is level with an exterior surface (e.g. at least one of the rear surface 104 and the lateral surfaces 106) of the electronic device 100. The one or more pins housed in the connector housing 252 will be described in more detail with reference to FIGS. 5A to 7B. The cable assembly 250 may also include a cable 254 mechanically connected to the connector housing 252. For example, one end of the cable 254 may be linked to a surface of the connector housing 252. The cable 254 may have one or more conductive tracks formed thereon which correspond and are electrically coupled to the pins located in the connector housing 252. For example, the pins located in the connector housing 252 may each include a connection portion which projects out of the connector housing 252. The cable 254 may include holes sized to fit these connection portions of the pins which project out of the connector housing 252. The cable 254 may then be arranged so that, after adaptation of the connection portions through the holes in the cable 254, the connection parts of the pins and the holes are welded so as to establish an electrical connection between the pins and the conductive tracks electrically coupled to the holes.
Cable 254 can be any thin cable. For example, the cable 254 can be a single- or multi-conductor cable in which the electrical conductors are guided parallel and adjacent to each other. Cable 254 may include tracks or conductive strips. Each strip can have a cross section of any shape, such as circular, oval, square, rectangular, etc. The conductive tracks or strips can be composed of any conductive material. For example, they can be made of tin, copper, etc. The conductive tracks or strips can be insulated using any insulating material, such as polyester, dielectric polymers, etc. In some embodiments, the cable 254 should be thin enough not to interfere with or disturb the electronic device 100 when the electronic device 100 is disposed in the recessed region of the body 212. For example, the cable 254 may have a diameter of 0.8 mm, between 0.5 mm and 1 mm, less than 0.5 mm or more than 1 mm. The cable 254 can have a cross section of any shape, such as circular, oval, square, rectangular, etc. According to certain embodiments, the cable 254 can be flexible or rigid. For example, in one embodiment, the cable 254 can be a substantially flat flexible cable. In another embodiment, the cable 254 may be a rounded or otherwise thicker cable which passes through a channel (not shown) in the body 212 to connect the connector housing 252 to the connector base 256.
The cable 254 can be disposed between the electronic device 100 and the recessed region of the body 212, and extend from an opening of the body 212 to an edge of the electronic device 100 (eg an edge of the upper surface 102, a location on a lateral surface 106 or an edge of the lateral surface 106). For example, the cable 254 can extend from the opening to the side 106 including the female connector 114. The cable 254 can also extend in a direction substantially parallel to said one or more pins housed in the connector housing 252 and towards the female connector 114. The connector housing 252 can be mechanically coupled to one end of the cable 254 near an edge of the electronic device 100. For example, the connector housing 252 can be mechanically coupled to one end of the cable 254 to proximity of the side 106 comprising the female connector 114. The opening of the body 212 will be described in more detail with reference to FIGS. 3A to 3E. The cable assembly 250 may also include a connector base 256. The connector base 256 may include a printed circuit board (not shown) having one or more connection pads formed thereon. The connection pads can be electrically coupled to respective conductive tracks of the cable 254. The connector base 256 can be disposed in the opening of the body 212. For example, the connector base 256 can be arranged so as to s extend partially into the body 212. In another example, the connector base 256 may be arranged to extend completely through the body 212. The connector base 256 may be mechanically coupled to the connector housing 252 via the cable 254. For example, the connector base 256 can be linked to one end of the cable 254 opposite to one end to which the connector housing 252 is linked. In some embodiments, the connector base 256 is coupled to the connector housing 252 only by the cable 254. The cable assembly 250 may also include a wire 258 which, in some embodiments, can be isolated. The wire 258 can comprise one or more wires (isolated in certain embodiments), at least one of the wires being coupled to the connection pads in the connector base 256. In addition, the wire 258 can be placed in an elongated cutout. of the docking station 210 which extends from the opening to an edge or an edge surface of the body 212. For example, the wire 258 can be located in an elongated cutout which extends inside the body 212. In another example, the wire 258 can be located in an elongated cutout which extends along a lower surface of the body 212. The elongate cutout of the body 212 will be described in more detail with reference to FIGS. 3A to 3E .
In certain embodiments, the digital signage system 200 comprises one or more flexible pads (not shown) disposed between the electronic device 100 and the docking station 210. The pads can be made from any type of flexible material; for example, they can be made from silicone, rubber, fabric, soft plastic, etc. The studs can be used to fix the electronic device 100 to the docking station 210. For example, the studs can be linked both to the electronic device 100 and to the docking station 210 so as to mechanically couple the electronic device 100 at the docking station 210. The pads can also be used to enable the activation of buttons arranged on the rear surface 104 of the electronic device 100. For example, one or more pads can be flexible, so that a force applied to the upper surface 102 of the electronic device 100 has the effect of deforming one or more studs 220, causing the engagement of a button located on the rear surface 104 in a surface of the recessed region of the docking station 210.
In other embodiments, there are no pads. Instead, the electronic device 100 can be mechanically coupled to the docking station 210 by other means; for example, the electronic device 100 can be glued or linked to the docking station 210; in another example, clamps can be provided for mechanically coupling the electronic device 100 to the docking station 210. In other embodiments, the electronic device 100 is arranged in the recessed region of the docking station 210 without mechanical coupling; for example, the recessed region of the docking station 210 can be dimensioned so that the electronic device 100 fits securely inside the recessed region; in another example, the electronic device 100 can be attached to the docking station 210 by the effect of gravity. In yet other embodiments, both pads and other means for mechanically coupling the electronic device 100 to the docking station 210 are provided.
FIG. 3A represents a perspective view of a docking station 300 intended to receive a cable assembly according to an embodiment of the present invention. As shown in Figure 3A, the docking station 300 includes a body 302. In some embodiments, the body 302 is substantially transparent; in other embodiments, the body 302 is opaque. A substantially transparent body 302 formed in accordance with certain embodiments of the present invention advantageously makes it possible to hide from view different elements depending on the angle of view. For example, when looking at one side of the transparent body 302, a user may not be able to see parts of a cable assembly due to light refractions caused by the geometry of the body 302.
In certain embodiments, the body 302 can be made from any material capable of forming a substantially solid entity. In other embodiments, the body 302 can be made from any material capable of forming a malleable and / or flexible entity. For example, body 302 can be made from a suitable metal, mineral, ceramic, ceramic glass, wood, polymer, composite material, semiconductor, nanomaterial or biomaterial. According to one embodiment, the body 302 is made from acrylic or an equivalent of acrylic. According to another embodiment, the body 302 is made from combinations of the above materials.
The body 302 includes an upper surface 304, a lower surface 306, a front (or side) surface 308, a rear (or side) surface 310 and side surfaces 312. The body 302 also includes a recessed region 314 formed on the surface upper 304.
The recessed region 314 is configured to receive an electronic device so that, when the electronic device is positioned in the recessed region, an exposed surface such as a display of the electronic device is substantially level with a peripheral portion of the surface surrounding the hollowed out region. For example, the recessed region 314 can be shaped to form a substantially inverted image of the rear surface 104, and optionally of the side surfaces 106, of the electronic device 100. By giving such form to the recessed region 314, when the electronic device 100 is positioned inside the recessed region 314, the upper surface 102 of the electronic device 100 can be substantially level with a peripheral part of the upper surface 304 which surrounds the recessed region. Furthermore, when the electronic device 100 is positioned inside the recessed region 314, the entire rear surface 104, and optionally all the lateral surfaces 106, of the electronic device 100 are contiguous to a surface of the recessed region 314. According to one embodiment, the hollowed out region 314 comprises curved surfaces 314a and a substantially planar surface 314b. For example, the curved surfaces 314a can be shaped to receive curved surfaces 104a from the electronic device 100, and a substantially planar surface 314b can be shaped to receive a substantially planar surface 104b from the electronic device 100.
According to another embodiment, the recessed region 314 does not include a substantially planar surface. Instead, the entire recessed region 314 is curved, so that there are substantially no planar surfaces in the recessed region 314. For example, when the electronic device 100 includes an entire rear surface 104 which is curved , so that there are substantially no planar surfaces in the rear surface 104, the recessed region 314 can be profiled accordingly so that the entire recessed region 314 is curved so as to correspond to the rear surface 104 of the device electronic 100.
The recessed region 314 can be arranged to receive electronic devices having exposed surfaces of a variety of shapes. For example, the recessed region 314 can be profiled to receive an electronic device 100 having a rectangular upper surface 102. The hollowed out region 314 can also be adapted to receive a square, circular, oval, etc. upper surface 102.
The upper surface 304 may be sloping upwards from the front surface 308 to the rear surface 310, so that the hollowed out region 314 is also sloping upwards from the front surface 308 to the rear surface 310. For example, a height of side surfaces 312 disposed near the front surface 308 may be smaller than a height of side surfaces 312 disposed near the rear surface 310. Therefore, the upper surface 304 may be sloping upward the front surface 308 to the rear surface 310 relative to the lower surface 306. In certain embodiments, the upper surface 304 may be sloping upward at an angle of about 7 ° relative to the lower surface 306. In other embodiments, the upper surface 304 may be sloped upward at an angle between about 4 ° and 10 °. In yet other embodiments, the upper surface 304 can be sloped upward at an angle of less than 4 ° or more than 10 °. By tilting the upper surface 304 relative to the lower surface 306, the visibility of an exposed surface of a mounted electronic device 100 (e.g. the upper surface 102) can be increased when the docking station 300 is placed on a horizontal surface.
The docking station 300 may include an opening 316 formed at least partially through the body 302 from the recessed region 314 towards the lower surface 306. In one embodiment, the opening 316 extends only partially in the body 302 , so that the opening 316 ends inside the body 302. In another embodiment, the opening 316 extends entirely through the body 302, so that the opening 316 ends at the lower surface 306 of the body 302. The opening 316 can be dimensioned to receive a cable assembly capable of connecting to an electronic device when the electronic device is mounted inside the recessed region. For example, the opening 316 may have an inverted image shape of the connector base 256 and have a diameter larger than a diameter of at least one of the connector housing 252 and the wire 258. From this way, at least one of the connector housing 252 and the wire 258 can pass through the opening 316 while the connector base 256 can fit perfectly inside the opening 316.
The docking station 300 may comprise an elongated cutout (not shown in FIG. 3A) which extends from the opening 316 to an edge (e.g. edges of the front surface 308, of the rear surface 310 or of side surfaces 312) or an edge surface (eg front surface 308, rear surface 310 or a lateral surface 312) of the body 302. The elongated cutout can be dimensioned so that a cable from a cable assembly can adapt to inside the opening.
For example, the elongated cutout can be dimensioned to receive the wire 258.
According to one embodiment, the elongated cutout extends inside the body 302. For example, when the opening 316 ends inside the body 302, the elongated cutout can extend from the termination point to inside the body 302 at the rear surface 310 of the body 302. According to another embodiment, the elongated cutout extends along the lower surface 306 of the body 302. For example, when the opening 316 ends at the lower surface 306 of the body 302, the elongated cutout can extend from the termination point to the lower surface 306 of the body 302 to a lower edge of the body 302.
Figure 3B shows a top view of the docking station 300 shown in Figure 3A. It is visible in the top view that the recessed region 314 can be profiled to receive the electronic device 100 having an upper surface 102 that is substantially rectangular. The corners of the recessed region 314 and of the upper surface 304 may be rounded or have substantially perpendicular angles. The opening 316 can be provided at any location inside the hollowed-out region 314. According to one embodiment, the opening 316 is located at a center of the hollowed-out region 314. According to other embodiments, the opening 316 is provided at a location offset from the center of the recessed region 314; for example, the opening 316 may be provided at a location closer to the front surface 308 than to the rear surface 310, closer to the rear surface 310 than to the front surface 308 and / or closer to a side surface 312 than from another lateral surface 312. The opening 316 can be arranged with any orientation inside the hollowed out region 314. According to one embodiment, the opening 316 is arranged so that the lateral surfaces of the opening 316 are parallel to the side surfaces 312. According to other embodiments, the opening 316 is arranged so that the side surfaces of the opening 316 are arranged at an angle between 0 and 90 degrees relative to the lateral surfaces 314.
Figure 3C shows a rear view of the docking station 300 shown in Figure 3A. The rear view shows an end portion of the elongated cutout 318. According to the embodiment shown in FIG. 3C, the elongated cutout 318 extends along the lower surface 306 of the body 302. According to another embodiment embodiment, as mentioned previously, the elongated cutout 318 may extend inside the body 302. In such a case, the end portion of the elongate cutout 318 may appear as a circle disposed on the rear surface 310 between (but not in contact with) the upper surface 304 and the lower surface 306.
As mentioned previously, the elongated cutout 318 can be dimensioned to receive the wire 258. In one embodiment, the wire 258 has a substantially circular cross section and the elongated cutout 318 has a substantially circular cross section having a diameter slightly larger than the diameter of the wire 258. For example, the diameter of the elongated cutout 318 can be about 10% larger than the diameter of the wire 258. The diameter of the elongated cutout 318 can also be larger by less or more than 10% than the diameter of the wire 258. In another embodiment, the elongated cutout 318 has a cross section having a curved portion and planar portions. The smallest diameter of the elongated cutout 318 may be larger than the largest diameter of the wire 258. In other embodiments, the wire 258 has a cross section of different shapes; for example, wire 258 may have an oval, square, rectangular cross section, etc. The elongated cutout 318 can then be shaped and dimensioned similarly to correspond to the size and shape of the wire 258.
Figure 3D shows a side view of the docking station 300 shown in Figure 3A. The side view makes it possible to see the elongated cutout 318. According to the embodiment shown in FIG. 3D, the elongated cutout 318 extends along the lower surface 306 from the opening 316 to the rear surface 310. According to a in another embodiment, as mentioned above, the elongated cutout 318 can extend inside the body 302. In such a case, the elongate cutout 318 can be moved vertically from the lower surface 306, so that the elongate cutout 318 is disposed between (but not in contact with) the upper surface 304 and the lower surface 306. As mentioned previously, the docking station 300 may include an opening 316 formed at least partially through the body 302 of the recessed region 314 towards the lower surface 306. According to the embodiment shown in FIG. 3D, the opening 316 extends entirely through the body 302, so that the opening 316 s e ends at the lower surface 306 of the body 302. According to another embodiment, as mentioned previously, the opening 316 can extend only partially in the body 302, so that the opening 316 ends inside of the body 302. In such a case, the opening 316 can be moved vertically from the lower surface 306, so that the opening 316 is disposed between the recessed region 314 and the lower surface 306, but not in contact with the surface lower 306.
As also mentioned previously, the opening 316 can be dimensioned to receive a cable assembly capable of being connected to an electronic device when the electronic device is mounted inside the recessed region. In one embodiment, the opening 316 comprises a first part 316a and a second part 316b. The first part 316a is set back from the recessed region 314 and extends from the recessed region 314 towards the lower surface 306, while the second part 316b is set back from the first part 316a and extends from the lower surface 306 towards the hollowed out region 314. A diameter of the first part 316a can be greater than a diameter of the second part 316b. In addition, an upper part of the connector base 256 can have a larger diameter than a diameter of a lower part of the connector base 256. The first part 316a can be dimensioned to receive the upper part of the connector. connector base 256, while the second part 316b can be dimensioned to receive the lower part of the connector base 256. In this way, when the opening 316 receives the connector base 256, an upper surface of the the connector base 256 can be substantially level with a surface of the recessed region 314.
Figure 3E shows a bottom view of the docking station 300 shown in Figure 3A. The bottom view shows the opening 316 and the elongated cutout 318. According to the embodiment shown in FIG. 3E, the opening 316 extends entirely through the body 302 and the elongated cutout 318 extends the along the lower surface 306 of the opening 316 to the rear surface 310. According to another embodiment, as mentioned previously, the opening 316 can extend only partially in the body 302 and the elongated cutout 318 can extend inside the body 302. In such a case, neither the opening 316 nor the elongated cutout 318 would be visible in this view.
Figure 4 shows a cable assembly 400 according to an embodiment of the present invention. The cable assembly 400 may include a connector housing 402, a cable 404, a connector base 406, a wire 408, and a pull tab 410. The connector housing 402, cable 404, connector base 406 and wire 408 may include some or all of the features of connector housing 252, cable 254, connector base 256, and wire 258 mentioned above.
In addition or as a replacement, the connector base 406 may include an upper part 406a and a lower part 406b. An upper surface of the upper part 406a can receive one end of the cable 404. For example, the upper part 406a can have a slot for receiving the cable 404. In certain embodiments, one end of the cable 404 can be linked to a card circuit board included in the connector base 406. In other embodiments, the cable 404 can be linked to a slot in the connector base 406. A lower surface of the lower part 406b can receive the wire 408 For example, the lower part 406b may include a slot for receiving the wire 408. In certain embodiments, one end of the wire 408 can be linked to a printed circuit board included in the connector base. In other embodiments, the wire 408 can be linked to the slot of the connector base 406.
Wire 408 may include one or more wires. The one or more wires can be linked to a printed circuit board located in the connector base 406. In certain embodiments, each of the one or more wires is surrounded by an insulating sheath. In other embodiments, the one or more wires are individually insulated and grouped in an additional insulating sheath. Any part of the wire 408 can be linked to the lower part 406b of the connector base 406. For example, an additional insulating sheath grouping together several wires can be linked to the connector base 406.
The pull tab 410 is a flat flexible element mechanically coupled to an electrical connector and can be used to disconnect the electrical connector from an electronic device. For example, the pull tab 410 can be mechanically coupled to the connector housing 402 and used to remove the connector housing 402 from the female connector 114. As previously mentioned, the connector housing 402 can be designed to fully fit inside the female connector 114 and have a rear surface which matches the shape and is level with an external surface of the electronic device 100. Thanks to such a design, the provision of the pull tab 410 can advantageously increase the ease removing the connector housing 402 from the female connector 114. In one embodiment, the pull tab 410 comprises a first part and a second part. The first part is mechanically coupled to a surface of the connector housing 402 oriented in parallel with pins arranged in the connector housing 402. For example, the first part can be linked to an upper surface of the connector housing 402. In another example, the first part can be bonded to a surface inside the connector housing 402. In yet another example, the first part can be formed as a part of the connector housing 402. The second part extends from the first part. The pull tab 410 can be any type of flexible element. For example, the pull tab 410 may be a ribbon, a tape-like structure, or a woven tape. The pull tab 410 can be made from any type of material producing a flexible element. For example, the pull tab 410 can be made from silicone, rubber, fabric, soft plastic, etc.
Thanks to its flexibility, the second part of the pull tab 410 can be arranged in the same plane as the first part. For example, the second part may extend from the first part in parallel with pins arranged in the connector housing 402. In this way, a force applied to the pull tab 410 to remove the connector housing 402 from the female connector 114 may reduce the risk of damage to the pins disposed in the connector housing 402 when removing the electrical connector from the electronic device.
Also thanks to its flexibility, the second part of the pull tab 410 is able to curve around a rear surface of the connector housing 402 and a lower surface of the connector housing 402. For example, the pull tab pull 410 can curve around the rear and bottom surfaces of the connector housing 402 and extend parallel and substantially adjacent to the cable 404. In this way, the pull tab 410 can be hidden from view if the assembly cable 400 is incorporated into a digital signage system.
The pull tab 410 can be of any shape and size allowing a user to disconnect the electrical connector from the electronic device. For example, the pull tab 410 may be rectangular, square, oval, etc. The pull tab 410 may have a width W extending over an entire upper surface of the connector housing 402. Alternatively, the pull tab 410 may have a width W extending only over a portion of the upper surface of the connector connector housing 402. In one embodiment, the pull tab 410 has a width W approximately equal to 2 cm. In another embodiment, the pull tab 410 has a width W approximately equal to 1 cm or 3 cm. In another embodiment, the pull tab 410 has a width W of between 0.5 cm and 5 cm. In yet another embodiment, the pull tab 410 has a width W of less than 0.5 cm or more than 5 cm. In one embodiment, the pull tab 410 has a length L approximately equal to 10 cm. In another embodiment, the pull tab 410 has a length L approximately equal to 20 cm. In another embodiment, the pull tab 410 has a length L of between 5 cm and 30 cm. In yet another embodiment, the pull tab 410 has a length L of less than 5 cm or more than 30 cm.
In some embodiments, the pull tab 410 may be temporarily bonded to the cable 404 by an adhesive or other bonding agent. For example, the pull tab 410 may be temporarily bonded to the cable 404 so that the pull tab 410 curves around the rear and bottom surfaces of the connector housing 402 and extends parallel and substantially adjacent to the cable 404 Such a temporary connection advantageously makes it possible to reduce interference from the pull tab 410 during the insertion of the connector housing 402 into a female connector.
FIG. 5A is a front perspective view of a male electrical connector 500 according to an embodiment of the present invention. The electrical connector 500 includes a connector housing 502 having a depth D and an interior cavity 504 adapted to accommodate one or more pins 506 which extend inside the interior cavity 504 in the direction of the depth D. The housing connector 502 includes an upper surface 508, a lower surface 510, a front surface 512, a rear surface 514 and side surfaces 516. The rear surface 514 extends between the upper surface 508 and the lower surface 510. The upper surface 508, the lower surface 510, the front surface 512 and the lateral surfaces 516 can establish engagement and contact with interior surfaces of the female connector 114 when the male connector 500 is connected to the electronic device 100. During such a connection , the rear surface 514 may be exposed. According to one embodiment, the lateral surfaces 516 are substantially parallel to one another. According to other embodiments, the lateral surfaces 516 are inclined at an angle greater than 0 degrees relative to each other. According to one embodiment, the upper surface 508 and the lower surface 510 are substantially parallel to each other. According to other embodiments, the upper surface 508 and the lower surface 510 are inclined at an angle greater than 0 degrees relative to each other.
The connector housing 502 and, therefore, the surfaces and interior cavity 504 of the connector housing 502 are shaped to fit a female connector such as the female connector 114 of the electronic device 100. The connector housing 502 may include various features to increase the quality of fit with the female connector 114. For example, the connector housing 502 may include a pair of elongated slots 518 extending from the front surface 512 in the direction of depth D and along from the bottom surface 510. The elongated slots 518 can receive protrusions from the female connector 114 and can be arranged in parallel with each other and / or in parallel with the lateral surfaces 516. The elongated slots 518 can include cutouts of the lower surface 510 having a cross section of any shape to receive corresponding projections, p For example, a rectangular cross section, a circular cross section, etc. In one embodiment, the elongated slots 518 extend partially through the connector housing 502 toward the rear surface 514. In another embodiment, the elongated slots 518 extend entirely through the connector housing 502 to 'to the rear surface 514.
The connector housing 502 may include additional or different features to increase the quality of fit with the female connector 114. For example, the connector housing 502 may include a pair of recesses 520 extending from the front surface 512 in the direction of the depth D and along the upper surface 508. The recessed portions 520 can receive projections from the female connector 114 and can be arranged in parallel with each other and / or in parallel with the lateral surfaces 516. The recessed portions 520 may comprise cutouts of the upper surface 508 having a cross section of any shape to receive corresponding projections, for example a rectangular cross section, a circular cross section, etc. In one embodiment, the recessed portions 520 extend partially through the connector housing 502 toward the rear surface 514. In another embodiment, the recessed portions 520 extend entirely through the connector housing 502 up to 'to the rear surface 514.
According to one embodiment, the connector housing 502 comprises an upper plate 507 and a lower plate 509. The upper and lower plates extend between the lateral surfaces 516 and the rear surface 514 extends from the upper plate 507 to the lower plate. 509. The internal cavity 504 is formed between the upper and lower plates and extends from a front edge of the connector housing 502 in the direction of the depth D. The internal cavity 504 is designed to accommodate one or more pins 506. By For example, pins 506 may include a plurality of pins positioned at pin locations spaced in a single row along the width W of connector housing 502. For each pin 506, the top plate 507 may include a cutout allowing the pin flex when engaged with a receiving pin in the female connector 114. The lower plate 509 can co mprendre, inside the cavity 504, a substantially planar upper surface for the engagement of a projecting part of the female connector 114.
The elongated slots 518 can be formed on the lower plate 509 between the interior cavity 504 and the sides 516 and extend from a front edge of the connector housing 502 in the direction of the depth D. For example, a first of the elongate slots 518 can be formed between a first side of the connector housing 502 and the interior cavity 504, and a second of the elongated slots 518 can be formed between a second side of the connector housing 502 and the interior cavity 504, the second side being opposite the first side.
The recessed portions 520 may be formed at an outer edge of the upper tray on the sides 516 and extend from a front edge of the connector housing 502 in the direction of the depth D. For example, a first of the recessed portions 520 may be formed at an outer edge of the upper plate 507 on the first side of the connector housing 502 and a second of the recessed portions 520 can be formed on an outer edge of the upper plate 507 on the second side of the connector housing 502.
The connector housing 502 can have cross sections of a wide variety of shapes. For example, in a plane parallel to the upper surface 508, the lower surface 510, the front surface 512 or the rear surface 514, the connector housing 502 may have a substantially rectangular cross section. In a plane parallel to the side surfaces 516, the connector housing 502 may have a substantially trapezoidal cross section.
One or more pins 506 may include one or more electrical conductors. In one embodiment, one or more pins include 30 pins. In another embodiment, one or more pins include less than 30 pins; for example, one or more pins may include 9 pins. In yet another embodiment, one or more pins comprise more than 30 pins. One or more pins 506 can be used to communicate electrical signals representing any type of data. For example, one or more pins 506 may include first and second differential data pins to communicate a data stream, a ground pin to provide ground voltage, a power pin to provide voltage, etc.
According to certain embodiments, the first part of the pull tab 410 can be linked to all or part of the upper surface 508 or to all or part of the upper plate 507. According to other embodiments, part of the surface upper 508 or part of the upper plate 507 is hollowed out to form a hollowed out part 508a. In such embodiments, the first part of the pull tab 410 can be linked to all or part of the recessed part 508a.
FIG. 5B is a perspective view from behind of a male electrical connector 500 according to an embodiment of the present invention. As mentioned previously, the rear surface 514 extends between the upper surface 508 and the lower surface 510. In one embodiment, the rear surface 514 is inclined relative to the front surface 512. For example, as shown in the figure 5B, the rear surface 514 can be inclined so that a depth of the connector housing 502 at the upper surface 508 is greater than a depth of the connector housing 502 at the lower surface 510. In another example, the rear surface 514 can be tilted so that a depth of the connector housing 502 at the top surface 508 is less than a depth of the connector housing 502 at the bottom surface 510. In some embodiments, the rear surface 514 is not tilted relative to the front surface 512. For example, the rear surface 514 can be substantially perpendicular to at least one of the surface s upper 508 and the lower surface 510. In some embodiments, the connector housing 502 may include an upper plate and a lower plate as mentioned above. In such cases, the rear surface 514 can be tilted so that a depth from the connector housing 502 to the upper plate 507 is greater than or less than a depth from the connector housing 502 to the lower plate 509. For example, the rear surface 514 can be inclined inwards from the upper plate 507 to the lower plate 509. In other embodiments, the rear surface 514 corresponds to the front surface 512. For example, the rear surface 514 and the front surface 512 can be arranged parallel to each other. In another example, the rear surface 514 and the front surface 512 can be inclined inward or outward by the same angle.
In one embodiment, the rear surface 514 is curved with respect to the front surface 512. For example, as shown in FIG. 5B, the rear surface 514 can be convex, so that the rear surface 514 is projecting from to the connector housing 502 in a direction away from the front surface 512. In another example, the rear surface 514 may be concave, so that the rear surface 514 is recessed inward toward the surface frontal 512. In certain embodiments, the rear surface 514 is not curved relative to the front surface 512. For example, the rear surface 514 may be substantially flat. In other embodiments, the rear surface 514 can be both curved and tilted.
In some embodiments, the rear surface 514 is curved and / or inclined to conform to an outline of an exterior surface of an electronic device in which a corresponding female connector is housed, so that when the connector housing 502 is completely inserted and coupled with the corresponding female connector, the rear surface 514 is level with the external surface of the electronic device. For example, the rear surface 514 can be curved and / or inclined to conform to an outline of an exterior surface of the electronic device 100. In certain embodiments, the exterior surface can be a lateral surface 106; in other embodiments, the outer surface can be the rear surface 104. Thanks to such an inclination and / or curvature of the rear surface 514, when the connector housing 502 is completely inserted and coupled with a corresponding female connector of the electronic device 100, such as a female connector 114, a rear surface 514 is level with the external surface (eg a lateral surface 106 and / or the rear surface 104) of the electronic device 100.
As mentioned previously, the connector 500 comprises one or more pins 506. Each pin 506 comprises a connection part 522 for mechanical and electrical coupling to a corresponding hole on the cable 254. Consequently, each connection part 522 can be shaped to the engagement of a corresponding hole on the cable 254. For example, the connection part 522 can be shaped into a cylinder. In another example, the connecting portion 522 can have a cross section in the shape of a circle, oval, square, rectangle, etc.
In one embodiment, when the pin 506 is mounted in the connector housing 502, the connection portion 522 may protrude or extend from the connector housing 502. For example, the connection portion 522 may extend in a direction substantially perpendicular to the rear surface 514. In some cases, the rear surface 514 may be curved. In such cases, the connection portion may extend in a direction substantially perpendicular to a planar surface which is tangential to the curved rear surface 514.
In another embodiment, pairs of pins 506 disposed adjacent to each other have connecting portions 522 which are staggered or vertically offset from each other. For example, a pair of pins 506 may comprise a first connection part 522a associated with a first of the pair and a second connection part 522b associated with a second of the pair. The first connection part 522a can extend from the rear surface 514 so that it is located closer to the lower surface 510 than to the upper surface 508, while the second connection part 522b can extend from the rear surface 514 so that it is located closer to the upper surface 508 than to the lower surface 510. The staggering of the connection portions 522 of adjacent pins 506 advantageously makes it possible to reduce the contact interference between adjacent pins 506 when coupled to holes on cable 254.
In still other embodiments, the connection parts 522 of all or part of the pins 506 can be arranged substantially parallel to one another, so that they are arranged substantially in the same plane between the lateral surfaces 516.
According to certain embodiments, the first part of the pull tab 410 can be linked to all or part of the upper surface 508 or to all or part of the upper plate 507. According to other embodiments, part of the surface upper 508 or a part of the upper plate 507 is hollowed out so as to form a hollowed out part 508a. In such embodiments, the first part of the pull tab 410 can be linked to all or part of the recessed part 508a.
FIG. 5C is a perspective view of a male electrical connector 500 coupled to a cable 254 according to an embodiment of the present invention. As mentioned previously, the cable 254 can comprise holes for receiving connection parts 522 from one or more pins 506. For example, the cable 254 can comprise one or more holes 524 arranged spatially to receive the connection parts 522. In in some embodiments, the pairs of pins 506 disposed adjacent to each other have connection portions 522 which are staggered or vertically offset from each other. Therefore, the pairs of holes 524 arranged adjacent to each other can be staggered or vertically offset in a similar fashion. In other embodiments, all or part of the holes 524 can be arranged substantially parallel to one another, so that they are arranged substantially in the same plane between the lateral edges of the cable 254.
In one embodiment, the cable 254 comprises a first part and a second part. The first part is mechanically coupled to the rear surface 514. As mentioned previously, the first part can be mechanically coupled by welding together the connection parts of the pins and holes 524. Thanks to this coupling to the rear surface 514, the first part may be curved to match an outline of the rear surface 514 and, in some embodiments, an exterior surface of an electronic device. The second part extends from the first part.
Thanks to its flexibility, the second part of the cable 254 can be arranged in the same plane as the first part. For example, the second part can extend from the first part in a direction substantially parallel to the rear surface 514. Thanks also to its flexibility, the second part of the cable 254 is able to curl around the lower surface 510. For example, the cable 254 can curve around the bottom surface 510 and extend parallel to a direction in which the pins disposed in the connector housing 502 extend. In this way, the cable 254 can be hidden from the view when the cable assembly is incorporated into a digital signage system.
Figure 6A is a side view of a pin disposed in a male electrical connector 600 according to an embodiment of the present invention. The connector 600 comprises a connector housing 602 which can be manufactured from any material capable of forming a substantially solid non-conductive entity. For example, the connector housing 602 can be made from composite materials, semiconductors, plastics, etc.
The connector housing 602 includes an upper shelf 604 and a lower shelf 606. The upper shelf 604 and the lower shelf 606 can cooperate to provide a friction fit or a clamp fit for a pin 650. That is, that when mounting the pin 650 in the connector housing 602, a position of the pin 650 inside the connector housing 602 can be substantially maintained by frictional forces between the connector housing 602 and the pin 650 .
Pin 650 includes various features which, alone or in combination, allow connector housing 602 and pin 650 to form a low profile male connector. In general, pin 650 includes a base 652 for supporting pin 650 inside the connector housing 602, an elongated body 654 extending from base 652 and an engaging portion 656 located on one end of the body elongated 654 opposite the base 652 for engagement in a receiving pin of a corresponding female connector.
In one embodiment, the base 652 includes a bottom surface 658 for mating with and engagement in the bottom shelf 606. For example, the bottom surface 658 may be substantially planar. Such coupling and engagement can increase the quality of the friction fit between the connector housing 602 and the pin 650. In another embodiment, the base 652 includes a cutout 660 to extend a length of the elongated body 654. As shown in FIG. 6A, the cutout 660 can have a triangular cross section. However, cutout 660 may have cross sections of other shapes; for example, in the shape of a square, rectangle, circle, oval, etc. Extending the length of the body advantageously reduces the intensity of the rotational forces applied to the spindle 650 and of the stresses inside the spindle 650 when it is engaged in a receiving spindle.
In particular, reducing the size of the electrical connectors generally requires reducing the size of the pins housed in the connectors. By reducing the size of these pins, we increase the intensity of the rotational forces applied to these pins and the intensity of the stresses inside these pins during the engagement of these pins in receiver pins. For example, when the length of a spindle decreases, the stiffness of the spindle increases accordingly. By increasing the rigidity of the spindle, a rotational force applied to the spindle due to engagement in a take-up spindle increases accordingly. Such rotational forces can, after only a few engagements, disadvantageously cause permanent rotation of the spindle outside of its original position, thereby reducing the quality of the electrical connection between the spindle and the receiving spindle. In addition, by increasing the rigidity of the spindle, the stresses inside such spindles are increased. For example, increasing the rigidity of the spindle results in an increase in the stress at the junction of a body and a base of such a spindle when the spindle is engaged in a receiving spindle. Such increased stress can, after only a few engagements, disadvantageously cause permanent deformation or, in some cases, rupture of the spindle.
Therefore, in some embodiments, the base 652 includes a cutout 660. The cutout 660 can advantageously increase the length of the elongated body 654 while maintaining a friction fit through the bottom surface 658, thereby allowing the pin 650 to maintain its position in connector housing 602 by reducing the likelihood of rotation, deformation or breakage of the pin.
In some embodiments, the base 652 may include a connection portion 662. As mentioned previously, the connection portion 662 may protrude from the connector housing 602 to establish a mechanical and electrical connection with a hole 524 in the cable 254.
In one embodiment, the base 652 includes one or more barbs for engagement in a connector housing. For example, the base 652 may include a barb 664 for engagement in the upper shelf 604. To enable such engagement, the upper shelf 604 may include a slot or cut in which the barb 664 moves when the pin 650 is mounted in the connector housing 602. The barb 664 may include a leading edge 664a and a stop edge 664b. The leading edge 664a can be inclined at an angle relative to the upper surface 666 of the base 652 to allow the pin 650 to be inserted into the connector housing 602. The stop edge 664b can be substantially perpendicular to the upper surface 666 to resist withdrawal of the pin 650 from the connector housing 602. This advantageously makes it possible to maintain a position of the pin 650 in the connector housing 602.
In another embodiment, the elongated body 654 may include a limit stop 668 projecting from an upper surface 670 of the elongate body 654. The limit stop 668 may have a cross section of any one of plurality of forms. For example, as shown in FIG. 6A, the end stop 668 can have a cross section which is substantially rectangular; in other examples, the cross section may be substantially square, circular, oval, etc. The limit stop 668 can be disposed along the elongated body 654 at a predetermined distance 'd' from the base 652. For example, 'd' can be equal to approximately 1/5 of the length Ί 'of the elongated body 654. In another example, 'd' can be between approximately 1/10 and 2/5 of the length Ί '. In yet another example, 'd' may be less than 1/10 or greater than 2/5 of the length Ί '.
By placing the end stop 668 at a predetermined distance from the base 652, the end stop 668 can be used to distribute a force applied to the elongated body 654 when engaging the engaging portion 656 in a receiver pin. For example, if no end stop is provided, when the elongated body 654 is deflected due to the engagement in a receiving pin, a significant stress can be applied at the junction of the elongated body 654 and the base 652. However, if an end of travel stop is provided, during the deflection of the elongated body 654 due to the engagement in a take-up spindle, part of the rotational force causing the stress at the junction is distributed to the tablet upper 604 by means of the end of travel stop 668. Such a distribution advantageously makes it possible to reduce the stress at the junction and, consequently, the probability of a deformation or of a rupture of the spindle.
In still other embodiments, the engaging portion 656 includes a leading edge 656a which is inclined at an angle to the top surface 670 to allow the pin 650 to be engaged in a pin receptor. According to one embodiment, the leading edge is provided at an angle of approximately 45 degrees relative to the upper surface 650. In other embodiments, the leading edge is provided at an angle between 40 and 50 degrees. In yet other embodiments, the leading edge is provided at an angle of less than 40 degrees or greater than 50 degrees.
Figure 6B is a side view of a pin 650 disposed in a male electrical connector 600 engaged in a receiving pin 680 according to an embodiment of the present invention. As mentioned previously, the pin 650 can be engaged in a receiving pin 680. The receiving pin 680 can be arranged, for example, in a female connector 114 of the electronic device 100. When engaging the pin 650 in the receiving pin 680, pin 650 can be caused to deflect. For example, the spindle 650 can be made to deflect vertically towards the upper shelf 604. As mentioned previously, such a deviation can impose stresses at the junction of the elongated body 654 and the base 652, which can, in certain embodiments , be attenuated by a cutout 660 in the base 652 to increase the length of the elongated body 654. In addition, as mentioned above, the deflection forces can tend to rotate the spindle 650; for example, they may tend to rotate the spindle 650 in a direction R. In some embodiments, however, such rotational forces can be reduced by incorporating an end stop 668.
Figure 7A is a side view of a pin 700 according to a first embodiment of the present invention. The pin 700 can be made from any type of rigid conductive material. For example, pin 700 can be made from one or more metals such as copper, nickel, tin or magnesium. Pin 700 includes a base 702 for supporting pin 700 inside a connector housing, an elongated body 704 extending from base 702 and an engaging portion 706 located on an opposite end of the elongated body 704 at base 702 for engagement in a receiving pin with a corresponding female connector. The base 702 includes a connection part 708.
According to one embodiment, as shown in Figure 7A, the connection portion 708 extends from an upper edge of the pin 700. The connection portion 708 can extend from the upper edge to any of a variety of 'angles. For example, the connection portion 708 may extend at an angle of about 45 degrees relative to a direction in which the elongated body 704 extends from the base 702. In another example, the connection portion 708 may extend at an angle of between about 30 and 60 degrees from a direction in which the elongated body 704 extends from the base 702. In yet another example, the connecting portion 708 may extend at an angle less than 30 degrees or more than 60 degrees relative to a direction in which the elongate body 704 extends from the base 702. In one embodiment, as shown in FIG. 7A, the connecting portion 708 extends in a direction oriented towards a lower surface of the base 702. In another embodiment, the connection part 708 extends in a direction oriented towards an upper surface of the base 702.
Figure 7B is a side view of a pin 700 according to a second embodiment of the present invention. According to one embodiment, as shown in Figure 7B, the connection portion 708 extends from a bottom edge of the pin 700. The connection portion 708 can extend from the bottom edge to any of a variety of 'angles. For example, the connection portion 708 may extend at an angle of about 45 degrees relative to a direction in which the elongated body 704 extends from the base 702. In another example, the connection portion 708 may extend at an angle of between about 30 and 60 degrees from a direction in which the elongated body 704 extends from the base 702. In yet another example, the connecting portion 708 may extend at an angle less than 30 degrees or more than 60 degrees relative to a direction in which the elongate body 704 extends from the base 702. In one embodiment, as shown in Figure 7B, the connecting portion 708 extends in a direction oriented away from an upper surface of the base 702. In another embodiment, the connecting portion 708 extends in a direction in a direction oriented toward the upper surface of the base 702.
With reference to both Figures 7A and 7B, the pin 700 can have any of a plurality of predetermined dimensions. For example, the pin 700 may have a total length L_pin of approximately 4.7 mm or a total length of approximately 4.3 mm. In a variant, L_pin can be between approximately 4 mm and 5 mm or less than 4 mm or more than 5 mm. In another example, the spindle 700 can have a total height H_pin of approximately 1.5 mm or 1.4 mm. In a variant, H_pin can be between approximately 1.2 mm and 1.8 mm or less than 1.2 mm or greater than 1.8 mm. In another example, the pin may have a depth or thickness (not shown) of approximately 0.2 mm, between approximately 0.15 mm and 0.25 mm or less than 0.15 mm or greater than 0.25 mm.
Different elements of pin 700 can have any of a plurality of predetermined dimensions. For example, the base 702 can have a length L_base of approximately 1.3 mm or 1.4 mm. In a variant, L_base can be between approximately 1 mm and 1.7 mm or less than 1 mm or greater than 1.7 mm. The base 702 can have a height H_base approximately equal to H_pin. In another example, the elongated body 704 may have a length L_shaft of about 2.7 mm or 2.8 mm. In a variant, L_shaft can be between approximately 2.2 mm and 3.2 mm or less than 2.2 mm or more than 3.2 mm. The elongated body 704 can have a height H_shaft approximately equal to 0.2 mm or 0.25 mm. In a variant, H_shaft can be between 0.15 mm and 0.3 mm or less than 0.15 mm or more than 0.3 mm. In another example, an end stop of the elongated body 704 can have a length L_1 imitas top approximately equal to H_shaft. The limit stop can have a height H_limit_stop also approximately equal to H_shaft. In another example, the engaging part 706 can have a length L_engaging_portion approximately equal to 0.7 mm or 0.8 mm. In a variant, L_engaging_portion can be between 0.5 mm and 1 mm or less than 0.5 mm or more than 1 mm. The engagement part 706 can have a height H_engaging_portion approximately equal to 0.6 mm or 0.7 mm. In a variant, H_engaging_portion can be between approximately 0.3 mm and 1 mm or less than 0.3 mm or more than 1 mm.
Various embodiments of improved connectors, cable assemblies and connector pins according to the present invention have been described. Although these inventions have been described in the context of the specific embodiments above, many modifications and variations are possible. The description above therefore only has an illustrative character and is not intended to be in any way limiting. In addition, the references above or below, or at the front and rear of the various structures described above are relative and used interchangeably according to the reference point. Likewise, the dimensions and sizes given throughout the above description are given only by way of illustration and the inventive concepts described therein can be applied to structures of different dimensions.

权利要求:
Claims (3)
[1" id="c-fr-0001]
1. A cable assembly (250), characterized in that it comprises: a male connector with a housing (252) arranged to be housed entirely in a female connector (114) of an electronic device (100), the connector male having a rear surface (514) shaped so as to be level with a surface (104, 106) of the electronic device (100); a plurality of pins (506) located in the male connector housing, each pin having an engagement portion for contacting a corresponding pin of the female connector, and a connection portion (522) extending to the surface back ; and a cable (254) connected to the plurality of pins located in the male connector. 2. The cable assembly of claim 1, wherein the cable (254) is substantially flat. 3. The cable assembly of claim 2, wherein the cable (254) is a flexible cable. 4. The cable assembly of claim 1, further comprising a pull tab (410) connected to the male connector. 5. The cable assembly of claim 4, wherein the pull tab (410) is a tape or strip. The cable assembly of claim 1, wherein the cable (254) is connected to the connector portions of the pins. The cable assembly of claim 6, wherein the cable (254) can be disposed along a rear surface (104b) of the electronic device (100). 8. The cable assembly of claim 1, wherein the cable comprises a plurality of conductors, each conductor being connected to a connection portion of a pin to a rear surface of the male connector. 9. The cable assembly of claim 8, wherein the plurality of conductors are arranged in parallel.
[2" id="c-fr-0002]
10. A cable assembly (250), characterized in that it comprises: a male connector with a front surface (512), an upper surface (508), a lower surface (510) and lateral surfaces (516), intended to be housed in a female connector (114) of an electronic device (100), the male connector having a rear surface (514) shaped so as to be substantially level with an external surface of the electronic device adjacent to the female connector; a plurality of pins (506) located in the male connector housing, each pin having an engagement portion for contacting a corresponding pin of the female connector, and a connection portion (522) extending to the surface back ; and a cable (254) connected to the connection portions of the plurality of pins located in the male connector. The cable assembly of claim 10, wherein the cable (254) comprises a plurality of conductors, each conductor being connected to a connection portion of a pin to a rear surface of the male connector. The cable assembly of claim 11, wherein the plurality of conductors are arranged in parallel. 13. The cable assembly of claim 12, wherein the cable (254) is substantially flat. 14. The cable assembly of claim 13, wherein the cable (254) is a flexible cable. 15. The cable assembly of claim 14, wherein the cable (254) can be disposed along a rear surface (104b) of the electronic device. 16. The cable assembly of claim 10, further comprising a pull tab (410) connected to the male connector. 17. The cable assembly of claim 16, wherein the pull tab (410) is a tape or strip.
[3" id="c-fr-0003]
18. A cable assembly (250), characterized in that it comprises: a male connector with a housing (252) arranged to be housed in a female connector (114) of an electronic device (100), the male connector having a rear surface (514) shaped so as to be substantially level with a surface (104, 106) of the electronic device (100) adjacent to the female connector (114); a plurality of pins (506) located in the male connector housing, each pin having an engagement portion for contacting a corresponding pin of the female connector, and a connection portion (522); and a cable (254) having a plurality of conductors arranged in parallel, each conductor being connected to a connection portion of a pin of the plurality of pins located in the male connector. 19. The cable assembly of claim 18, wherein the cable (254) can be disposed along a rear surface (104b) of the electronic device. 20. The cable assembly of claim 18, wherein the connection portions of the plurality of pins extend toward the rear surface (514) of the connector housing.

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FR3088228A1|2020-05-15|DEVICE FOR HOLDING AT LEAST ONE CABLE ON A PRINTED CIRCUIT DURING WELDING

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WO2010037979A1|2010-04-08|Connection assembly and system for connecting a planar cable to a base, and method for making same

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EP2568492B1|2016-01-06|Interface part between an electronic card and the control panel thereof, mechanical interface made up of one or more of said parts and device including such a mechanical interface

同族专利:

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公开号 | 公开日

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US20120295487A1|2012-11-22|

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RU2012120669A|2013-11-27|

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GB201208760D0|2012-07-04|

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RU2532249C2|2014-11-10|

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CN102856749B|2015-04-08|

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WO2012162255A1|2012-11-29|

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US9142908B2|2015-09-22|

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JP2012243774A|2012-12-10|

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CN102856749A|2013-01-02|

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US20140256186A1|2014-09-11|

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US8727812B2|2014-05-20|

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GB2491243A|2012-11-28|

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US8414337B2|2013-04-09|

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AU2012202946A1|2012-12-06|

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GB2491243B|2014-04-09|

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FR2975539A1|2012-11-23|

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US20130217269A1|2013-08-22|

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DE102012208328A1|2012-11-22|

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JP5571121B2|2014-08-13|

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AU2012202946B2|2014-11-20|

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法律状态:
2018-05-15| PLFP| Fee payment|Year of fee payment: 7 |

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2019-04-10| PLFP| Fee payment|Year of fee payment: 8 |

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2020-12-04| PLSC| Search report ready|Effective date: 20201204 |

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2021-02-12| ST| Notification of lapse|Effective date: 20210105 |

优先权:

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申请号 | 申请日 | 专利标题

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US13112995|2011-05-20|

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US13/112,995|US8414337B2|2011-05-20|2011-05-20|Low profile male connector|

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FR1254572A|FR2975539A1|2011-05-20|2012-05-18|MALE CONNECTOR WITH LOW PROFILE|

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