Patent Grant
9373909
1. Field
The present invention describes connectors for connecting two components and, more particularly, to water resistant connectors for forming a resilient connection.
2. Description of the Related Art
Connectors are used in various types of systems. It is always desirable to prevent liquids (and debris) from flowing into connectors because, over time, any liquid that enters a plug or a receptacle may corrode or otherwise damage the internal components. Some connectors are used in medical settings, such as hospitals, to connect devices, such as an MRI device or an X-ray device, to computing systems. Connectors for these types of equipment can be costly and, thus, it is especially desirable to prevent liquids from flowing into and damaging these costly connectors. Another desirable quality for connectors used in medical equipment is the ability to easily clean the connectors, especially a receptacle coupled to a bed or table, due to the highly sanitary nature of medical settings.
It is also desirable for connectors to remain in electrical connection in response to a disturbance causing movement of a plug relative to a socket. This, also, is especially true in medical settings as some imaging procedures may take a significant amount of time to complete and a significant amount of time may be lost if contacts of a plug momentarily separate from contacts of a receptacle. Connectors used in some medical settings may have a greater tendency to be subjected to disturbances due to the placement of the connectors. For example, in MRI systems, the connectors may be placed on a patient's bed such that a slight movement of the patient can potentially disconnect the plug from the receptacle.
In various systems, operators may be required to plug and unplug the connectors many times per day, such as in MRI systems where a coil may be replaced after nearly every scan. After sufficient repetitions of this plugging and unplugging, the operator may have a tendency to develop a repetitive motion injury. This is especially true if the amount of force required to unplug the connectors is relatively large. Thus, it is desirable for the connector to be easy to connect and disconnect.
Thus, a need exists in the art for connectors that tend to remain connected during disturbances, are relatively easy to clean, and require relatively little force to disconnect.
This Summary is included to introduce, in an abbreviated form, various topics to be elaborated upon below in the Detailed Description.
What is described is connector for use in an environment that is exposed to liquids or debris. The connector includes a receptacle having a body defining a plurality of apertures and having a mating face and a plurality of socket contacts each defining an opening aligned with one of the plurality of apertures. The connector also includes a plug having an outer casing defining a cavity and having a mating end and a plurality of contacts positioned within the cavity and coupled to the outer casing, each having a pin tip. The plug also includes a pin protection plate slidably coupled to the outer casing, enclosing at least a portion of each of the plurality of contacts within the cavity, and defining a plurality of pin guides each aligned with one of the plurality of contacts. When the mating end of the outer casing is aligned with the mating face of the pin protection plate and force is applied to the outer casing towards the body, the mating face resists movement of the pin protection plate and the pin tip of each of the plurality of contacts extends beyond the pin protection plate and is received by one of the plurality of socket contacts via one of the plurality of apertures of the body.
Also described is a connector for use in an environment exposed to liquids or debris. The connector includes a receptacle configured to be coupled to a surface and having a body defining a plurality of apertures and having a mating face. The receptacle also includes a plurality of socket contacts each defining an opening aligned with one of the plurality of apertures and having a termination end having at least one of a pin tip, a spring probe, or a contact surface. The connector also includes a plurality of bed contacts each including at least one of bed socket contact, a target contact, a plated through hole, or a bed contact surface. The connector also includes a plug having an outer casing defining a cavity and having a mating end. The plug also includes a plurality of contacts positioned within the cavity and coupled to the outer casing, each having a pin tip configured to be received by the opening of one of the plurality of socket contacts.
Also described is a connector for use in an environment exposed to liquids or debris. The connector includes a receptacle having a receptacle casing defining a plurality of contact apertures and having a mating surface. The receptacle also includes a plurality of target contacts each having a contact surface and positioned in one of the plurality of contact apertures such that the contact surface is flush with the mating surface. The connector also includes a plug having a plug casing defining a cavity and an insulator positioned with the cavity, coupled to the plug casing, having a mating face, and defining a plurality of probe apertures. The plug also includes a plurality of spring probes each coupled to the insulator, having a mating end, and extending through one of the plurality of probe apertures such that the mating end extends outward from the mating face.
Also described is a connector for use in an environment exposed to liquids or debris. The connector includes a receptacle having a receptacle casing having a mating surface, defining a plurality of contact apertures, and defining a first receiving slot and a second receiving slot. The receptacle also includes a plurality of receptacle contacts each having a mating end and a termination end and positioned in one of the plurality of contact apertures. The connector also includes a plug having a plug casing defining a cavity and a plurality of plug contacts each positioned within the cavity, coupled to the plug casing, and having a mating end configured to mate with the mating end of one of the plurality of receptacle contacts. The plug also includes a latch actuation collar positioned within the cavity and slidably coupled to the plug casing. The plug also includes two latches each in contact with the latch actuation collar and having a receptacle lip configured to be received by one of the first receiving slot or the second receiving slot. When the plug is connected to the receptacle and the latch actuation collar is moved relative to the plug casing, the receptacle lip of each of the two latches is removed from the corresponding one of the first receiving slot or the second receiving slot.
The features, obstacles, and advantages of the present invention will become more apparent from the detailed description set forth below when taken in conjunction with the drawings, wherein:
Apparatus, systems, and/or methods that implement the embodiments of the various features of the present invention will now be described with reference to the figures. The figures and the associated descriptions are provided to illustrate some embodiments of the present invention and not to limit the scope of the present invention. Throughout the drawings, reference numbers are re-used to indicate correspondence between referenced elements. A connection, when mentioned in this document, may refer to any communication channel between modules, and the communications may occur via a wired connection, a wireless connection, or a combination of the two.
A patient may be positioned on the bed 108 and the coil 106 may be positioned such that the coil 106 can detect images corresponding to a body part of the patient. In various embodiments, the imaging system 104 may not include the bed 108 and may instead include a chair for the patient to sit, a shelf for a patient's body part, or even no resting device for the patient.
The coil 106 may be coupled to a plug 100 via a cable 101. The plug 100 may receive the detected imaging data from the coil 106 via the cable 101. The bed 108 or another surface may include a receptacle 102 configured to receive the plug 100 such that the imaging data can be transferred from the plug 100 to the receptacle 102. In that regard, the plug 100 and the receptacle 102 together may be referred to as a connector 105. The receptacle 102 may be coupled to a cable 110 that is also connected to the computing device 112.
In some embodiments, the connector 105 may be used in systems other than imaging systems. For example, the connector 105 may be used in networking systems, computing systems, or any other type of systems in which data transfer occurs. Thus, where used herein, a bed may refer to any structure to which a receptacle is to be coupled.
With reference now to
The receptacle casing 206 defines a first receiving slot 200 on a forward end 210 of the receptacle casing 206 and a second receiving slot 202 on a back end 212 of the receptacle casing 206. The forward end 210 and the back end 212 may be substantially perpendicular to the mating surface 302, meaning that an angle between the mating surface 302 and either of the forward end 210 and the back end 212 may be an acute, an obtuse, or a right angle. The mating surface 302 may be connected to one or both of the forward end 210 and the back end 212 at an angle or via a curvature. In some embodiments, the receptacle casing 206 may have receiving slots at different locations than shown in
The forward end 210 of the receptacle casing 206 may be tapered. With brief reference to
With reference now to
The contact body 307 of the target contact 205 may have a diameter similar to the diameter of the contact aperture 301. Accordingly, the target contact 205 may be held in place relative to the receptacle casing 206 by static friction between the contact body 307 and the receptacle casing 206. The target contact 205 may also include a barb to resist movement of the target contact 205 relative to the receptacle casing 206. Barbs will be discussed in greater detail with reference to
In some embodiments, a portion of a target contact near the contact surface may have a cylindrical shape having a larger diameter than the contact body. Accordingly, the contact surface may match a counter-bored contact aperture of a receptacle casing.
With reference now to
With reference now to
Returning reference to
A target contact 400 may include a mating surface 401 and a surface mount feature, such as a contact surface, on a termination end 404. The contact surface may be soldered to a PC pad 402 of a PC board (PCB) 403, creating an electrical connection. The PCB 403 may have another contact in electrical communication with the PC pad 402 and coupled to a wire or sub-cable. The PCB 403 may be positioned on top of, or within, the bed 108. The target contact 400 may include a barb 406. The barb 406 is oriented such that the target contact 400 can be inserted into the receptacle casing 206 from the positive Z direction, as the barb is tapered towards the termination end 404. In that regard, after the target contact 400 is pressed into the receptacle casing 206, the barb 406 may reduce the likelihood of the target contact 400 becoming removed from the positive Z direction.
The target contacts may also include a target contact 410 having a contact surface 411 and a PC tail 412 extending from a termination end 414. The PC tail 412 may extend through a through-hole 413 of the PCB 403 that is plated with a conductive material. In that regard, when the PC tail 412 is positioned within the through-hole 413, solder may be applied, electrically (and mechanically, to an extent) coupling the PC tail 412 to the plating of the through-hole 413 and, thus, to the PCB 403. The target contact 410 may also include a barb 416 configured similarly to the barb 406.
The target contacts may also include a target contact 420 having a contact surface 421 and a spring probe 422 extending from a termination end 424. Characteristics and operation of spring probes will be described in greater detail below with reference to
The target contacts may also include a target contact 430 having a contact surface 431 and a PC tail 432, similar to the PC tail 412, extending from a termination end 424. However, instead of being soldered to a plated through-hole, the PC tail 432 may be received by a socket of a contact, such as a hyperboloid socket of a hyperboloid socket contact 433 or any other type of socket, such as a bifurcated socket, creating an electrical connection. Hyperboloid sockets will be described in greater detail below with reference to
The target contacts may also include a target contact 440 having a contact surface 441 and a spring probe 442 extending from a termination end 444. Force may be applied to the spring probe 442 towards the bed 108 such that the spring probe 422 contacts a contact surface 445 of another target contact 443, creating an electrical connection. As with the hyperboloid socket contact 433, the target contact 443 may extend through the bed 108 and be coupled to a wire or sub-cable at a termination end.
The target contact 440 may also include a barb 446 that functions similarly to the barb 406. However, the barb 446 may begin at the contact surface 441 and taper towards the termination end 444. Because the barb 446 is positioned adjacent the contact surface 441, it may further reduce the likelihood of liquids flowing into the outer casing 206 of the receptacle.
The target contacts may also include a target contact 450 having a contact surface 451 and crimping cavity 452 at a termination end 454. A tip 453 of a wire or sub-cable 455 may be positioned within the crimping cavity 452 and the termination end 454 may be crimped, coupling the tip 453 of the wire or sub-cable 455 to the target contact 450, creating an electrical and mechanical connection. The target contact 450 may include a barb 456 being tapered towards the mating surface 302 of the receptacle 102. Because the target contact 450 will be crimped to a wire, it is easier to insert the target contact 450 into the receptacle 102 from the negative Z direction. Thus, the barb 456 is configured to reduce the likelihood of the target contact 450 becoming removed from the receptacle 102 in the negative Z direction.
The target contacts may also include a target contact 460 having a contact surface 461 and a solder cup 462 at a termination end 464. The solder cup 462 may receive a tip 463 of a wire or sub-cable 465. While the tip 463 is within the solder cup 462, solder may be applied to the solder cup 462, electrically and mechanically coupling the tip 463 to the target contact 460. The target contact 460 may also include a barb 466 configured similarly to the barb 456.
Occasionally, contacts within the receptacle 102 may require service. Target contacts having certain termination styles may require more effort to service than other target contacts. For example, using a target contact similar to the target contact 450 may require a relatively large amount of effort because the receptacle 102 will likely need to be de-coupled from the bed 108, the target contact 450 removed from the bottom of the receptacle, the wire or sub-cable 455 is cut, and the wire or sub-cable is re-crimped to the new target contact.
With reference now to
With reference now to
With reference now to
A plug in use with the sleeve contact of
With reference now to
Returning to
The plug 100 may also include one or more release actuators including a release actuator 502 on a first side 512 of the plug casing 500 and a release actuator 609 (shown in
With reference now to
The collar body 610 may further define spring slots 622 including a spring slot 622A on the second side 514 and a spring slot 622B on the first side 512. The spring slots 622 may be open and receive compression springs 604 from the top (i.e., from the positive Z direction). The spring slot 622A may receive a compression spring 604A and the spring slot 622B may receive a compression spring 604B. The compression springs 604 may extend upwards from the collar body 610 and be compressed when the plug 100 is assembled, such that the compression springs 604 may exert a repulsion force between the plug casing 500 and the latch actuation collar 606. Thus, when the plug 100 is fully assembled, the latch actuation collar 606 may be positioned a maximum distance from the non-mating face 506 of the plug casing 500.
An insulator 634 may be tapered at the forward end 501, allowing it to be received by the plug casing 500 and may define a plurality of probe apertures 644 including a probe aperture 645. The insulator 634, as with the plug casing 500, the latch actuation collar 606, and the latches 624A and 624B, may comprise a material having low conductivity, such as a plastic, thermoplastic, composite, or other material, and each may or may not include the same material. The probe apertures 644 may each receive one of a plurality of spring probe contacts 631, including a spring probe contact 632, each having a spring probe on a mating end and another spring probe or other type of connection on the termination end. The insulator 634 may include a feature, such as detents within the spring probe contacts 631, an interference fit between the insulator 634 and each of the plurality of probe apertures 644, for resisting movement of the plurality of spring probe contacts 631 relative to the insulator 634. Similarly, the spring probe contacts 631 may include barbs or other features for resisting movement relative to the insulator 634.
The spring probe contact 632 may have a mating end 652 and a termination end 650. For example, the probe aperture 645 may receive the spring probe contact 632 such that both ends of the spring probe contact 632 may extend through the probe aperture 645. The mating end 652 may extend from the insulator 634 in the negative Z direction. Stated differently, the mating end 652 may extend outward from a mating face 802 (shown in
The insulator 634 may also include a plurality of screw slots 642 spaced apart about the perimeter of the insulator 634. The plug 100 may also include a plurality of screws 646 that may extend through the screw slots 642 and screw into the plug casing 500. In some embodiments, the spring probe contacts 631 may be held in place between the insulator 634 and the plug casing 500 when the insulator 634 is coupled to the plug casing 500.
The collar body 610 may define an actuation slot 620 on the forward end 501 and an actuation slot 621 on the back end 510. The actuation slots may each receive a portion of one or more latches 624. For example, the actuation slot 620 may receive a collar lip 628 of a latch 624A.
The insulator 634 may further define a latch slot 636 on the forward end 501 and a latch slot 638 on the back end 510. The latch 624A may extend through the latch slot 636 and a latch 624B may extend through the latch slot 638. In that regard, a portion of the latch 624A between a receptacle lip 626 and an inner rounded portion 630 may be aligned with the insulator 634 when the latches 624 are in position. In some embodiments, the inner rounded portion 630 may be in contact with a portion of the insulator 634 designed for receiving the inner rounded portion 630.
With reference now to
A termination end 700 of the spring probe contact 632 may include a means for coupling the spring probe contact 632 to a wire or other component. In that regard and with reference to
Because the moveable tip 704 is forced towards the mating surface 306, the connection between the moveable tip 704 and the mating surface 306 remains intact in response to vibration or other force that may tend to separate other connectors. With reference to
With reference now to
With renewed reference to
With reference now to
Because the collar lip 628 is received by the actuation slot 620, this movement of the latch actuation collar 606 relative to the insulator 634 causes the inner rounded portion 630 to rotate clockwise relative to the insulator 634. This clockwise rotation of the latch 624A causes the receptacle lip 626 to separate from the second receiving slot 202. The latch 624B may rotate counterclockwise relative to the insulator 634 and release in a similar manner. Removal of the receptacle lips from the receiving slots of the receptacle 102 allows the plug 100 to move relative to, and thus detach from, the receptacle 102.
When the plug 100 is released from the receptacle 102, the force exerted on the release actuator 608 and the release actuator 609, as well as any other force applied to the plug 100 in the positive Z direction, may cause the plug 100 to move upward relative to the receptacle 102. Additionally and with reference to
With reference now to
The hyperboloid socket contact 433 may include a first collar 914 and a second collar 916, each resembling a cylinder. The hyperboloid socket contact 433 may include a plurality of wires 912 each coupled to and extending between the first collar 914 and the second collar 916. The plurality of wires 912 may resemble a hyperboloid, such that a diameter of the hyperboloid socket of the hyperboloid socket contact 433 is at a minimum between the first collar 914 and the second collar 916 and increases towards the first collar 914 and the second collar 916. In that regard, when the hyperboloid socket receives the termination end 424 of the target contact 410, the PC tail 432 of the termination end 424 may force the wires 912 outward, such that a force is exerted from each of the wires 912 onto the termination end 424. An outer barrel (not shown) may surround the first collar 914, the second collar 916, and the plurality of wires 912. The hyperboloid socket contact 433 may also include a termination end 918 for connecting with any style of contact.
With reference now to
With reference directed now to
With reference now to
With renewed reference to
In some embodiments, the receptacle 1002 may be configured to receive pin tips. In that regard, the mating surface 1106 may define a plurality of apertures 1108 having a sufficient diameter such that a pin or pin tip may extend through the plurality of apertures 1108.
A contact retention plate 1120 may include a plurality of contact retention features 1122, including a contact retention feature 1124, for receiving a plurality of hyperboloid socket contacts 1003, including a hyperboloid socket contact 1004. The contact retention plate 1120, as with the body 1006 and the protective cap 1100, may comprise a material having a low conductivity, such as a plastic or other insulating material, and each may or may not include the same material. The hyperboloid socket contact 1004 may have a mating end 1140 defining an opening to the hyperboloid socket of the hyperboloid socket contact 1004 and a termination end 1142. The mating end 1140 may be inserted through the contact retention plate 1120 such that each of the hyperboloid socket contacts 1003 is received by one of the contact retention features 1122. As described below, the contact retention features 1122 may include a feature that reduces the likelihood of each of the hyperboloid socket contacts 1003 moving relative to the contact retention features 1122. When the contact retention plate 1120 is coupled to the body 1006, each of the hyperboloid socket contacts 1003 may be coupled to the body 1006 and aligned with one of the apertures 1108. Other methods of coupling the plurality of hyperboloid socket contacts 1003 to the body 1006 may be used without departing from the scope of the disclosure. Additionally, socket contacts other than hyperboloid socket contacts, such as bifurcated socket contacts, may be used without departing from the scope of the disclosure.
The contact retention plate 1120 may also define a plurality of screw holes 1126 configured to receive a plurality of screws 1130. In that regard, the screws 1130 may be inserted through the screw holes 1126 and into the body 1006, coupling the contact retention plate 1120 to the body 1006.
It may be desirable to prevent liquids from reaching the plurality of hyperboloid socket contacts 1003. In that regard, the receptacle 1002 may also include a protective cap 1100. The protective cap 1100 may be designed such that it can be received by the volume 1102 and remain in contact with the outer shell 1104, forming a seal with the outer shell 1104 and reducing the likelihood of liquid entering the volume 1102 and reaching one or more of the plurality of hyperboloid socket contacts 1003.
In some embodiments, the plurality of hyperboloid socket contacts 1003 may be formed using a stamping method, however, non-stamped hyperboloid contacts are also contemplated. For example and with reference to
The hyperboloid socket contact 1004 may also include a neck 1208 having a smaller diameter than the first annular portion 1200, the second annular portion 1202, and/or the contact portion 1204. In that regard and with reference to
With reference now to
However, the opening 1402 may be sufficiently large to receive a pin tip 1450 of a pin contact 1452. As the pin tip 1450 is inserted through the opening 1402 at the mating end, it may deform the elastic material 1400 and, thus, enlarge the opening 1402. Due to the elasticity of the elastic material 1400, the pin tip 1450 may extend through the opening 1402 and be received by the hyperboloid socket contact 1004. When the pin tip 1450 is removed, the elastic material 1400 returns to a relaxed state such that the diameter of the opening 1402 is again sufficiently small to reduce the likelihood of liquids reaching the hyperboloid socket contact 1004.
With reference now to
The outer casing 1504 may define a cavity 1601 (illustrated in
The cable sheath portion 1508 may have a tubular shape designed to receive a cable 1501. The cable 1501 may include a plurality of wires and/or sub-cables such that each of the wires/sub-cables may extend into the cavity 1601 and contact a termination end of one or more of the contacts. The cable sheath portion 1508 may reduce the likelihood of damage to the cable 1501.
With reference now to
A plurality of contacts 1624 having pin tips on a mating end 1629, similar to the pin contact 1452, may be positioned within the cavity 1601. As with the hyperboloid socket contact 1004 of
In various embodiments, the plug 1500 may include 60 contacts 1624 and the receptacle of
The plug 1500 may further include a contact retention plate 1630. The contact retention plate 1630 may define and/or include a plurality of pin receivers 1632. Each of the pin receivers 1632 may one of the contacts 1624 and retain the contact in a similar manner as the contact retention features 1122 grasp the hyperboloid socket contacts 1003 of
The plug 1500 may further include an insulator 1636 defining a plurality of apertures 1637 through which the contacts 1624 may extend. The insulator 1636 may further define two coupling holes 1645 that align with screw apertures 1634 of the contact retention plate 1630. A plurality of screws 1628 may extend through the screw apertures 1634 of the contact retention plate 1630 and be received by the two coupling holes 1645 of the insulator 1636, coupling the contact retention plate 1630 to the insulator 1636. In that regard, the contacts 1624 may be coupled to, and resist movement relative to, the insulator.
The outer casing 1504 may have an inner surface defining a first shelf 1620 and a second shelf 1622, each extending inward from the inner surface of the outer casing 1504. The insulator 1636 may include a first guide 1639A and a second guide 1639B that each may be received between shelves of the outer casing 1504. For example, the second guide 1639B may be received by a gap between the first shelf 1620 and the second shelf 1622. Due to similar dimensions of the insulator 1636 and the inner surface of the outer casing 1504 in the X and Y directions, when the guides 1639 are received by the gap between the shelves of the outer casing 1504 and the first shell 1600 is coupled to the second shell 1602, the insulator 1636 (and thus the contact retention plate 1630 and the contacts 1624) may be coupled to and resist movement relative to the outer casing 1504.
The insulator 1636 may further include a plurality of posts 1640 extending in the positive Z direction from the insulator 1636. The posts 1640 may define an area therebetween in which the contact retention plate 1630 and the bases of the contacts 1624 may be positioned.
The plug 1500 may further include a pin protection plate 1643. The pin protection plate 1643, as with the outer casing 1504, the contact retention plate 1630, and the insulator 1636, may comprise a material having low conductivity such as a plastic or other insulating material and each may or may not include the same material. The pin protection plate 1643 may define and/or include a plurality of pin guides 1656, including a pin guide 1658. A portion of each of the contacts 1624 may extend through one of the pin guides 1656.
The pin protection plate 1643 may further include a plurality of posts 1644 each defining a spring hole 1646. One of a plurality of compression springs 1642 may be received by each of the spring holes 1646 and extend in the positive Z direction from the posts 1644. The compression springs 1642 may contact the insulator 1636 and apply pressure thereto, applying a repulsion force between the pin protection plate 1643 and the insulator 1636 when in a resting state. In various embodiments, another feature may retain the compression springs 1642 in place relative to the insulator 1636 and the pin protection plate 1643.
The pin protection plate 1643 may further include two T-bars 1648, each positioned on one of the first side 1514 or the second side 1516. The two T-bars 1648 may each include an elongate portion 1650 and a cross portion 1652 positioned at the farthest end of the elongate portion 1650 in the positive Z direction from the pin protection plate 1643. The elongate portion 1650 may be inserted into connector slots 1641 defined by the insulator 1636 such that the T-bars 1648 allow movement of the pin protection plate 1643 relative to the insulator 1636. A distance of the cross portion 1652 in the X direction may be larger than a distance of the connector slots 1641 in the X direction, thus reducing the likelihood of separation of the pin protection plate 1643 from the insulator 1636 beyond a predetermined distance. When the plug 1500 is not coupled to a receptacle, the compression springs 1642 cause the pin protection plate 1643 to be separated from the insulator 1636 by the predetermined distance.
In some embodiments and with reference to
With reference now to
With reference now to
The static friction between the contacts 1624 and the hyperboloid socket contacts 1003 is sufficient to ensure that the plug 1500 remains connected to the receptacle 1002 until force is applied to the plug 1500 away from the receptacle 1002 (i.e., in the positive Z direction). However, the compression springs 1642 provide a negative unmating force between the plug 1500 and the receptacle 1002, reducing the amount of force necessary to disconnect the plug 1500 from the receptacle 1002.
In various embodiments and with reference to
With reference now to
Returning to
For example, the target contacts 204 include a target contact 1902 and a target contact 1904 that are adjacent each other and separated by a distance 1910. The target contact 1902 and the target contact 1904 may be coupled to wires/sub-cables used for a single ended connection having an impedance requirement of a first predetermined value. Similarly, the spring probe contacts 631 include a spring probe contact 1922 and a spring probe contact 1924 that are adjacent each other and separated by a distance 1930 that is substantially the same as the distance 1910. The spring probe contact 1922 and the spring probe contact 1924 maybe coupled to wires of the cable 101 for a single ended connection having an impedance requirement matching the predetermined value. Thus, when the plug 100 is coupled to the receptacle 102, a single ended signal can propagate through the connector 105 via the target contact 1902, target contact 1904, the spring probe contact 1922, and the spring probe contact 1924.
The target contacts 204 also include a target contact 1906 and a target contact 1908 that are non-adjacent and separated by a distance 1912. The distance 1912 may be greater than the distance 1910 such that the impedance between the target contact 1906 and the target contact 1908 may be greater than the impedance between the target contact 1902 and the target contact 1904. Thus, the target contact 1906 and the target contact 1908 may be coupled to wires of the cable 110 carrying a differential pair signal, which may have a greater impedance requirement. Similarly, the spring probe contacts 631 include a spring probe contact 1926 and a spring probe contact 1928 separated by a distance 1932 similar to the distance 1912, also having an impedance that allows propagation of differential pair signals. Thus, when connected, a differential pair signal can propagate through the connector 105.
In various embodiments, single ended signals and different pair signals may each be transmitted by adjacent pairs of target contacts 204 and spring probe contacts 631. For example, the target contact 1902 and the target contact 1904 may be coupled to wires of the cable 110 for a differential pair signal, and the target contact 1901 and the target contact 1903 may be coupled to wires of the cable 110 for a single ended signal. Similarly, the spring probe contact 1922 and the spring probe contact 1924 may be coupled to wires of the cable 101 for a differential pair signal, and the spring probe contact 1922 and the spring probe contact 1924 may be coupled to wires of the cable 101 for a single ended signal. This is possible due to the spacing of the contacts within the insulators of the plug 100 and the receptacle 102.
As described above, the distance between adjacent target contacts 204 and spring probe contacts 631 may be constant throughout the connector 105, yet the target contacts 204 and spring probe contacts 631 may be capable of carrying different types of signals. Additionally, the contacts of the connector 105 may be capable of transferring a multitude of non-radio frequency (RF) signals in additions to the single ended and differential pair signals described above. The receptacle 1002 and the plug 1500 may likewise be capable of transmitting and receiving various types of signals having various voltages and/or frequencies.
The previous description of the disclosed examples is provided to enable any person of ordinary skill in the art to make or use the disclosed methods and apparatus. Various modifications to these examples will be readily apparent to those skilled in the art, and the principles defined herein may be applied to other examples without departing from the spirit or scope of the disclosed method and apparatus. The described embodiments are to be considered in all respects only as illustrative and not restrictive and the scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.
This application claims the benefit and priority of U.S. Provisional Application No. 62/015,356, entitled “Connectors,” filed on Jun. 20, 2014, the entire contents of which are hereby incorporated by reference herein.
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| Number | Date | Country | |
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| 20150372414 A1 | Dec 2015 | US |
| Number | Date | Country | |
|---|---|---|---|
| 62015356 | Jun 2014 | US |
