High density connector.

专利摘要:
The invention relates to a pluggable electrical connector (2) with high density, which has a number of electrical contacts exceeding sixty, and a contact density on a mating interface (31) of the connector of at least forty contacts per square centimeter and a jacket (4) and a connector unit (6) mounted in the shell, the connector unit comprising a housing having a module receiving cavity formed in the housing and a plurality of connector modules insertable in the module receiving cavity in a stacked arrangement are included. Each connection module comprises a multiplicity of contacts which are mounted in a dielectric connection module housing, the connection modules having a ratio of width W to height H, W / H, which is greater than three. The invention also relates to a pluggable electrical connector system.
公开号:CH716325B1
申请号:CH01395/20
申请日:2019-05-16
公开日:2021-10-29
发明作者:Wolfe Charles；Glazier Richard；Matteri Paul；H Lee William
申请人:Lemo S A；
IPC主号:

专利说明:

The present invention relates to a high density pluggable electrical connector.
Certain applications require a large number of electrical contacts for signal, data and power connection in a single plug-in connector having a small diameter or cross-sectional area. Such connectors can be found, for example, in medical equipment or in test and measurement equipment. In certain applications, the number of electrical contacts required can exceed a hundred. In many prior art solutions, a plurality of connectors are provided to meet the requirement of a number of electrical connections. Conventional high density electrical connectors are difficult to connect to individual conductors of a cable. In addition, in a situation where an interconnection is defective, repairing the defective interconnection can also be very difficult and costly. Because the cable can be connected to expensive equipment, the ability to test and repair the high density electrical connector is often required.
In certain applications, for example medical applications exposed to strong magnetic fields, such as magnetic resonance imaging (MRI) and magnetic catheter navigation, an additional complication is the need to shield the electrical contacts from the strong magnetic field, which leads to size and complexity of the connector.
In view of the foregoing, it is an object of the invention to provide a high density pluggable electrical connector for applications requiring more than 50 contacts, with a total density at the mating interface of not less than 30 contacts per square centimeter, such that it is easy to use conductive lines can be interconnected, and can be easily tested and repaired if necessary.
It is advantageous to provide a high density pluggable electrical connector that can be easily modified for different uses or requirements.
It is advantageous to provide a high density pluggable electrical connector that is cost effective to manufacture and assemble.
In certain applications it is advantageous to provide a high density pluggable electrical connector that has good shielding against magnetic fields.
It is advantageous to provide a high density pluggable electrical connector, particularly for medical applications, that can be easily sterilized.
It is advantageous to provide a high density pluggable electrical connector that has a small overall diameter / size that allows it to be inserted into small spaces such as a catheter tube, handpiece, or handle medical instrument to fit.
It is advantageous to provide an electrical connector that is versatile and allows various connection techniques and options for interconnection with a cable and other conductive line arrangements.
It is advantageous to provide a high density pluggable electrical connector that has a low mating force with a mating connector but still provides reliable electrical interconnection.
Objects of this invention have been achieved by providing a high density connector according to claim 1.
Objects of this invention have been achieved by providing a high density pluggable electrical connector system according to claim 17.
Disclosed herein is a high density pluggable electrical connector comprising a shell and a terminal unit mounted within the shell, the terminal unit comprising a housing having a module receiving cavity formed within the housing and a plurality of terminal modules insertably received in the module receiving cavity in a stacked arrangement, each terminal module including a plurality of contacts mounted in a dielectric terminal module housing and a connection plate connected to the plurality of contacts.
The connector comprises a number of electrical contacts exceeding sixty and a contact density on a mating interface of the connector of at least forty contacts per square centimeter, the connection module having a ratio of width W to height H, W / H, of greater than three (W / H> 3).
The contacts of each terminal module include spring-loaded contact sections arranged in two rows that form a receiving slot configured to receive a received contact assembly of a mating connector therein.
The contacts of each connection module further comprise connecting sections at an end opposite the contact to the plug contact sections, which are designed for connection to the connecting plate.
In one embodiment, at least one of the connection modules comprises a magnetic shield that surrounds the connection module housing.
In an advantageous embodiment, the connecting plate comprises contact surfaces on a front edge of the connecting plate, which can be used between the connecting sections of the contacts for electrical interconnection therewith.
In an advantageous embodiment, the connection plate comprises wire connection surfaces which are arranged in at least two or more rows and at least five or more columns on both sides of the connection plate, preferably in at least three or more rows and at least eight or more columns on both sides of the connection plate are for connection to conductive wires or lines of a cable or conductor arrangement.
In one embodiment, the connection board may include electrical components for filtering signals or providing signal processing functions connected to one or more electrical circuit traces that interconnect the contact pads with the wire connection pads.
In an advantageous embodiment, the connection module includes insertion guide elements which cooperate with supplementary guide elements in the module receiving cavity of the housing to enable the insertion of each connection module into the housing at a defined plane in the stack of the plurality of connection modules.
In an advantageous embodiment, the guide element on the connection module has the form of an axially extending projection or bead which is received in a corresponding complementary, axially extending recess or groove in a side wall of the module receiving cavity.
In an advantageous embodiment, the connection module can have at least one locking element on a laterally smaller side of the connection module housing, which engages with at least one additional latching element in the side wall of the module receiving cavity.
In an advantageous embodiment, the guide elements on the housing and connection module are designed to allow the insertion of the plurality of connection modules in the connection housing in an axial direction (A), which corresponds to a plug-in direction of the connector with a mating connector, and around to be stacked on top of each other.
In one embodiment, the connector comprises a number of electrical contacts in excess of one hundred and a contact density at a mating interface of the connector of at least fifty contacts per square centimeter.
In an advantageous embodiment, the connector can further comprise electrical power contacts for electrical power supply, which are mounted directly in the housing of the connection unit and are positioned above and / or below the stack of modules.
In an advantageous embodiment, the connector can further comprise a magnetically shielded contact unit which is mounted in the connection housing above and / or below the stack of connection modules, the contact unit being a magnetic shielding shell, an insulating housing that can be inserted into the shielding shell , and one or a plurality of contacts that are mounted and carried in the insulating housing, wherein the shielded contact unit is insertably mounted in a corresponding cavity of the connection unit housing above and / or below the stack of connection modules.
The magnetic shield shell can advantageously have a cylindrical or generally cylindrical shape.
The magnetic shield shell can advantageously have a length to diameter ratio of at least three.
Also disclosed herein is a high density pluggable electrical connector system that includes any of the embodiments of the connector set forth above (the female connector) and a mating connector (the female connector) that can be plugged in and unplugged therefrom wherein the mating connector comprises a plurality of terminal modules in a stacked arrangement, each having or consisting of a connector plate having a plurality of contact surfaces extending in a juxtaposed manner along a leading edge of the connector plate for pluggable connection with a corresponding one of the plurality of contacts of the connector are arranged. The connector can be considered a female connector in view of the pair of rows of contacts forming a receptacle, and the mating connector can be considered the female connector in view of the connector plate male end insertable into the corresponding receptacle of the female connector.
In one embodiment, the mating connector may include a shell and a terminal unit mounted within the shell, the terminal unit including a housing with a module receiving cavity formed within the housing, the plurality of terminal modules insertable in are added to the module receiving cavity.
The terminal modules of the mating connector can advantageously consist of connection plates, the contacts thereon being formed by contact surfaces on the connection plates.
Similar to the connection plates of the connector described above, the connection plates of the mating female connector at an end distal from the male end advantageously wire connection surfaces arranged in at least two or more rows and at least five or more columns on either side of the connection plate, preferably in at least three or more rows and at least eight or more columns on either side of the connecting plate, are arranged, for connection to conductive wires or lines of a cable or conductor arrangement.
In an advantageous embodiment, the mating connector received may further comprise a magnetically shielded contact unit which is mounted in the connection housing above and / or below the stack of connection modules, the contact unit being an insulating housing which can be inserted into the magnetic shielding shell, and one or a plurality of contacts mounted and carried in the insulating housing, the shielded contact unit insertably being mounted in a corresponding cavity of the connection unit housing above and / or below the stack of connection modules.
Further objects and advantageous features of the invention will be apparent from the claims, from the detailed description and from the accompanying drawings; FIG. 1a is a side view of a high density pluggable electrical connector system in accordance with one embodiment of the invention illustrating a first connector pluggable to a mating second connector; Figure 1b is a cross-sectional view of the mating connector of Figure 1a; Figure 1c is an exploded perspective view of the first connector of Figure 1a; Figure 1d is an exploded perspective view of the second connector of Figure 1a; Figure 1e is a perspective cross-sectional view of a portion of the first and second connectors of Figure 1a; FIG. 2a is a perspective view of a connection unit of a pluggable high density electrical connector according to an embodiment of the invention, viewed from one side of the plug interface; FIG. 2b shows a perspective view of the connection unit from FIG. 2a and the connection plate, viewed from a terminating side; FIG. 2c shows a perspective view of the connection unit from FIGS. 2a and 2b, showing connection modules that have been removed from a housing of the connection unit; FIG. 3 shows a perspective view of a connection module of the first connector and a matching connection plate of the second connector of the embodiment of FIGS. 1a to 1e in an unplugged state; FIG. 4a shows a view of the plug-in interface side of the connection module from FIG. 3; FIG. 4b shows a cross-sectional view through the line IVb-IVb of FIG. 4a; FIG. 4c shows an exploded perspective view of the connection module from FIG. 4a; FIG. 5a is a perspective view of a terminal unit of a pluggable high density electrical connector with removed contacts according to an embodiment of the invention, viewed from a termination side; FIG. 5b shows an exploded view of the connection unit from FIG. 5a; FIG. 6a is a perspective view of a connection unit of the second connector of a pluggable, high-density electrical connector system according to a further embodiment of the invention, viewed from one side of the plug-in interface; FIG. 6b shows a perspective view of the connection unit from FIG. 6a, viewed from a terminating side, with connection modules shown outside the housing of the connection unit prior to assembly; FIG. 7a shows a perspective view of a connection module and matching connection module according to a further embodiment of the invention; FIG. 7b shows an exploded perspective view of the connection module from FIG. 7a; FIG. 7c shows a cross-sectional view of the connection module from FIG. 7a; FIG. 8a shows an exploded perspective view of a connection unit with the connection modules from FIG. 7a according to another embodiment of the invention; FIG. 8b shows an exploded perspective view of a matching connection unit with the matching connection modules from FIG. 7a according to a further embodiment of the invention; Figures 9a and 9b are perspective views of a connector unit of a female connector (Figure 9a) and a connector unit of a mating female connector (Figure 9b) of a high-density pluggable electrical connector system according to a further embodiment of the invention; FIG. 9c shows an exploded perspective view of some components of the connector system of FIGS. 9a, 9b; FIG. 9d shows a perspective view of magnetically shielded contact units of the connector system of FIGS. 9a, 9b; FIGS. 9e and 9f are perspective views of contact modules of the magnetically shielded contact units of FIG. 9d.
Referring to the figures, a high density pluggable electrical connector system 1 according to an embodiment of the invention comprises a high density pluggable electrical connector 2 and a mating electrical connector 2 ', the connectors 2, 2' in an axial direction A. are pluggable connectable and separable.
In the illustrated embodiment, the high density pluggable electrical connector 2 is adapted to terminate a multi-conductor cable (not shown), and the mating connector 2 'is adapted to be mounted on a panel or device (not shown). In the illustrated example, the mating connector 2 'comprises locking rings 34', 36 'at least one of which threadably engages external threads on the shell 4' to tighten / lock the connector 2 'to the panel or device.
Within the scope of the invention, however, instead of being a panel or device mounted connector, the mating connector may be a cable connector configured in a manner similar to the pluggable cable connector 2 for termination on a multi-conductor cable (not shown) is.
The high density pluggable electrical connector 2 according to embodiments of this invention includes a terminal unit 6 housed within the shell 4. The connection unit 6 comprises a dielectric housing 8, in which a multiplicity of connection modules 10 are inserted and fixed. The jacket 4 and the connection unit 6 have a plug-in interface 31, 30 for coupling to a supplementary plug-in interface of a mating connector 2 '.
The mating connector 2 'according to embodiments of this invention may also comprise a terminal unit 6' housed within a jacket 4 '. The connection unit 6 'comprises a dielectric housing 8', in which a multiplicity of connection modules 10 'are inserted and fixed. The jacket 4 'and the connection unit 6' have a plug-in interface 31 ', 30' for coupling to the plug-in interface 31, 30 of the pluggable electrical connector 2 with a high density.
In the illustrated embodiment of the high density pluggable electrical connector 2, the jacket 4 of the connector 2 extends axially from a cable exit end 29 to a mating interface 30 and includes an inner shell 32 mounted around a rear end of the terminal unit 6 and an outer shell 36, 34 which is mounted around the connection unit 6 and inner shell 32. The outer shell includes a locking ring 36 on the mating end that is inserted over a male end of the connector assembly and a locking ring 34 on the cable end that is mounted over a cable exit end of the inner shell. Further, a cable exit guide 28 can be provided which is coupled to the locking ring at the cable end. The inner shell 32 may, for example, be in the form of half-shells which enable assembly around the rear end of the connection unit 8, the inner shell and the connection unit being provided with interengaging positioning and locking means, such as complementary projections and recesses 39a, 39b, which lock the connection unit securely to the inner shell in a fixed axial and angular position.
The housing 4, 4 'of the connectors 2, 2' can be made of various materials, including, for example, metal, in order to provide a durable connector. The metallic housing can optionally also be connected to an electrical ground connection for electrical shielding of the connection unit 6, 6 ′ mounted therein. As a variant, the jacket can also comprise a magnetic shielding material to provide shielding from strong magnetic fields for applications in which the connector is exposed to strong magnetic fields, such as in MRI or other applications.
In the illustrated embodiment, the cable output end 34, 28 is axially aligned with the plug direction A, it is understood, however, that different cable output directions, such as a right angle or any oblique angle, are possible. In addition, the shape of the cable can be round or it can have various other shapes such as generally rectangular and flat. The cable output end can therefore have various configurations, as discussed above, without departing from the scope of protection of the invention. The jacket mating interface 30 includes guiding and locking elements for guiding and locking the connector to the mating connector. The inner shell 32 in the form of two or more inner shell parts, which are mounted laterally around the rear end of the connection unit 6, enables the connection unit to be connected to lines of a cable that passes through the cable outlet guide 28 and the locking ring 34 at the cable end without disturbing other sheath parts is used, whereby a simple repair or modification of the connection unit by the complete removal of the jacket locking rings 34, 36 and inner shell parts 32 is made possible. Such shell designs are known per se and need not be described further.
The housing 8 of the connection unit comprises a module receiving cavity 37 in which a plurality of connection modules 10 can be inserted in a stacked manner, as best illustrated in Figures 1e, 2a-2c, 5a, 5b.
The housing 8 'of the terminal unit of the mating connector 2' may also include a module receiving cavity 37 'in which a plurality of terminal modules 10' are insertably received in a stacked manner, as in Figures 1d, 1e, 6a, 6b is best illustrated.
Each terminal module 10 of the high density pluggable electrical connector 2 includes a plurality of electrical contacts 18 mounted in a dielectric terminal module housing 20. The dielectric housing 20 may be made from one or more pieces, either molded over the contacts 18 and / or assembled with the contacts 18. In a preferred embodiment, the electrical contacts 18 are advantageously arranged in two rows of contacts 19a, 19b. The pair of rows of contacts provide optimal access for connection to conductive lines of a cable or other conductive structure connected to the connector, as described in more detail below.
In the embodiment illustrated in FIGS. 4a to 4c, each row of contacts of the pair of rows of contacts 19a, 19b is carried by a first housing section 20a, for example overmolded by the first housing section 20a, and inserted into a second, outer housing section 20b. The free ends 43 of the contacts 18 at the plug interface end press against the inner surfaces 45 of the second, outer housing section 20b when the mating plug is inserted between the pair of opposing contacts 18.
In the embodiment illustrated in Figures 7a to 7c, the pair of rows of contacts 19a, 19b are separated from a first housing section 20c, which is positioned between the rows of contacts, second, outer housing sections 20d are assembled over the rows of contacts on opposite sides. The second, outer housing sections can be welded or bonded together, for example. In this embodiment, the opposing contacts 18 are resiliently biased towards one another, whereby when the mating connector is not inserted between the pair of opposing contacts 18, the free ends 43 of the contacts 18 at the mating interface end press against the outer surfaces 47 of the second outer housing portion 20d.
The contacts 18 extend from a plug contact portion 38 to a connecting portion 40 for connection to a connecting plate 12 or other conductive arrangement. The plug contact sections 38 are designed for pluggable connection with mating contacts of the mating connector 2 '.
In the illustrated embodiments, the plug contact sections 38 are in the form of spring contacts which comprise, for example, convex elastic rod sections which are arranged in two opposite rows of contacts 19a, 19b and thereby form a receiving slot 11 which is designed to accommodate a received contact arrangement of the mating connector 2 'to be incorporated therein.
As best illustrated in Figures 1b, 1e, 3, the mating connector 2 'may be provided with a connecting plate 13 comprising contact surfaces 15 arranged in a juxtaposed manner along a leading edge 17 of the connecting plate 13, wherein the contact pads are formed on opposite sides of the connection plate and are interconnected via conductive circuit traces (not shown) to wire connection pads 24 for connection to conductive lines of a conductor assembly (not shown) of the mating connector 2 '. The front edge 17 is inserted into the receiving slot 11 of the connection module 10 such that the spring contacts 38 on both sides of the receptacle of the connection module 10 press elastically against corresponding respective contact surfaces 15 on opposite sides of the connection plate 13 and clamp the connection plate 13 between them.
The connecting plates can be provided with locking elements, for example a locking recess 41b (see Figures 1c and 3), which engage in complementary locking elements, for example a locking rib 41a on the jacket, for example the inner shell 32 of the jacket. This secures the connection plates in the correct position in relation to the connection unit 6.
Other contact configurations known per se for pluggable contacts, which enable a high density of contacts, can be used without departing from the scope of protection of the present invention.
In the illustrated embodiments, the connecting sections 40 of the contacts 18 are designed for soldering or welding to a connecting plate 12 for each connection module 10. The connection plates 12 and corresponding connection modules 10 and the housing 8 are part of the connection unit 6. As can best be seen in FIGS for receiving an edge 27 of the connecting plate 12. The connecting plate 12 comprises a plurality of contact surfaces 25, which are provided on the front edge 27 on both sides of the plate, against which the corresponding connecting sections 40 of the contacts 18 are connected, in particular by soldering or welding; in a variant, the connecting sections 40 can include spring contacts, which are resiliently biased against the contact surfaces 25 to establish electrical connection therebetween.
The contact areas 25 are interconnected with wire connection areas 24 via conductive circuit traces on the board. The wire connection pads may advantageously be arranged in a spaced-apart manner in a plurality of rows and columns to provide a suitable spacing for making connection to leads of a cable or other conductor arrangement. Preferably there are at least three or more rows and at least eight or more columns of contact areas on either side of the connection plate.
Electronic or electrical components 26 may be mounted on the connection board 12, connected to one or more of the electrical circuit traces for filtering signals or providing other signal processing functions in the power paths of one or more conductors. The distribution of wire connection areas over a certain surface area of the plate advantageously facilitates the interconnection by welding, soldering or other techniques for connecting the wire and the plate and facilitates the repair or replacement of an interconnection.
Similarly, the interconnect plate 13 of the mating connector terminal module 10 'may include pads 15 interconnected by conductive circuit traces on the board and wire connecting pads 24 arranged in a plurality of rows and columns in a spaced apart manner to provide suitable clearance for making connections to leads of a cable or other conductor arrangement. Preferably there are at least three or more rows and at least eight or more columns of contact areas on either side of the connection plate. Electronic or electrical components 26 connected to one or more of the electrical circuit traces for filtering signals or providing other signal processing functions in the power paths of one or more conductors may also be mounted on the connection board 13.
The connection plates 12, 13 also advantageously enable the separation of the interconnection with conductive conductors or wires from the connection modules 10, 10 'and housings 8, 8', whereby the individual replacement, repair or testing of each connection module is facilitated independently of the other connection modules 10, 10 ', which can also be removed or exchanged independently. In addition, the interconnection of wires of a cable with the connection plates 12, 13 can be carried out separately from the configuration of the connection module 10, 10 ', thereby providing versatility in the connection arrangements without a change in the plug interface 31, 31' of the connector 2, 2 ' will.
The connector panels 12, 13 also provide easy access to opposite sides of the panels for wiring interconnection and, once inserted into the respective connector modules 10, 10 ', allow for a tightly stacked interconnection arrangement.
The connecting plates 12, 13 can be in the form of printed circuit boards or can be embossed and shaped, in particular from a printed circuit board embossed and shaped, contacts, the contacts being overmolded, stapled or assembled in an insulating body to form a one-piece to form formed connection module. In the embodiment illustrated in FIGS. 6a, 6b, the contacts 18 'are stamped metal contacts which are overmolded in an insulating body 20' in order to form unitary connection modules 10 "from one piece.
Within the scope of the invention, the connection module 10, 10 ', 10' 'by other means, such as direct bonding of wire and contact (welding, soldering) or insulation displacement contacts (IDC), with conductive lines or Wires of a cable or other conductive arrangement are connected. The connecting portions 40 of the contacts 18, 18 ', similar to the spaced apart arrangement of the contact pads 24, may have a staggered relationship to be arranged in a plurality of rows and columns to facilitate interconnection with conductive lines of a cable. The contacts 18, 18 'can be embossed and formed from a printed circuit board and overmolded, stapled, or assembled with an insulating body to form a single, one-piece connection module.
Each connection module 10 of the pluggable electrical connector 2 with high density can advantageously be provided with insertion guide elements 14 which cooperate with supplementary guide elements 14a in the module receiving cavity 37 of the housing 8 to allow the axial insertion of the connection modules in the housing at a defined To enable level in the stack of the plurality of connection modules 10. In the illustrated embodiment (FIGS. 2c, 5a), the guide element 14b on the connection module has the shape of an axially extending projection or bead which is received in a corresponding supplementary, axially extending recess or groove in the side wall 46 of the module receiving cavity 37 is.
Each connection module can advantageously have a ratio H / W between the total height H in the stacking direction Z and the total width W that is less than 30 percent and is preferably in the range from 20 to 30 percent. The above-mentioned ratio ensures an advantageous distribution of the electrical contacts, in particular to facilitate the interconnection with wires of a cable while at the same time providing a high connection density.
Each connection module can also be provided with snap-in elements 16b (see FIG. 5b), preferably on laterally smaller sides 44, which snap into the side wall 46 of the module receiving cavity 37 with additional snap-in shoulders 16a.
In one embodiment, one or more or each connection module 10 can comprise a magnetic shield 22 which surrounds the connection module housing 20 (see FIG. 5b). The magnetic shield 22 may, for example, be in the form of a magnetic material that is bent into a substantially rectangular shape to fit snugly around the terminal module housing 20, for example inserted in the axial direction A over it.
The supplementary guide elements 14a, 14b on the housing 8 and the connection module 10 are designed to allow the insertion of the plurality of connection modules in the connection housing in an axial direction A, which corresponds to an insertion direction of the connector, and to be stacked on top of each other will.
The mating connector 2 'can also comprise connection modules 10', 10 "which can be detachably fitted into a housing 8 'of a connection unit 6' with the same or similar features as described above for the connection modules of the pluggable cable connector 2, In particular, each connection module 10 'of the matching connector 2' can be provided with insertion guide elements 14b ', which are formed, for example, by lateral edges of the connection plates 13 or the overmolded body 20' and which are supplemented with Guide elements 14a 'in side walls 46' of the module receiving cavity 37 'of the housing 8' cooperate in order to enable an axial insertion of the connection modules 10 ', 10 "into the housing on a defined plane in the stack of the plurality of connection modules. The front wall 47 '(see FIG. 1e) of the housing 8' can also comprise slots through which the front ends of the connection modules 10 ', 10 "are inserted in order to securely position and hold the connection modules in the stacked arrangement.
In an advantageous embodiment, the connection modules 10, 10 ′, 10 ″ can be arranged such that they can be individually pulled out of the connection housing 8, 8 ′ in order to replace or repair a connection module, for example in the event of a defective one Plug contact section 38 or in the case of a defective interconnection with wires of a cable connected to the connector 2, 2 '.
In the embodiment illustrated in FIGS. 2a to 2b, each of the plurality of connection modules 10, 10 'of a connector 2, 2' is formed identically or essentially identically formed. In variants, connection modules with different configurations can be used in a connection housing. For example, for circular connectors (as illustrated), the top and bottom terminal modules of the stack may be less wide than the middle module (s).
The magnetic shield 22 may be provided around one, some, a plurality or each of the terminal modules 10 of the terminal unit 6. The shielding can also be provided in a similar manner for the terminal modules 10 ', 10 "of the mating connector 2'. For terminal modules that do not require magnetic shielding, e.g. for power or non-critical electrical contacts, the magnetic shielding can be omitted The magnetic shield 22, which is positioned around a corresponding connection module 10, 10 ', can be present in addition to a magnetic shield, which is positioned around the connection unit 6, 6', for example the jacket 4, 4 'with magnetic shielding properties.
In an advantageous embodiment, the plug interface 31, 31 'of the connector 2, 2' comprises more than forty contacts 18, 18 'per square centimeter, typically more than fifty contacts per square centimeter, for example in a range of 60 to 100 contacts per Square centimeters, allowing easy connection, testing and maintenance of conductive lines. The connector 2, 2 'according to embodiments of the invention can advantageously be used for connection to wire connectors in a range from 22 AWG (American Wire Gauge) (0.6438 mm diameter) to as small as 54 AWG (0.01575 mm diameter). be used.
The use of modular connection units enables maintenance replacement without renewed termination of all conductors of the cable. The high density of the contacts enables the use in applications with defined geometric restrictions, for example in an end piece of a medical instrument with predefined dimensions. The modular connection units also enable simple testing and, if necessary, reworking for simple validation tests outside the connection unit.
In addition to the connection modules 10, 10 ', the connectors 2, 2' can advantageously also include electrical contacts 21, 21 'that are suitable for the electrical power supply, which are called here power contacts 21, 21' that are connected via and / or positioned under the stack of modules. The power contacts are advantageously mounted in the housing 8, 8 'of the connection unit and are carried directly by it. The power contacts may advantageously comprise mating pin 21a 'and receptacle contact portions 21a on respective connectors 2, 2'. The power contacts 21, 21 ', which are mounted directly in the housing 8, 8' of the connection unit, advantageously enable an increased electrical power supply without disturbing the stacked arrangement of high-density signal lines.
With reference to FIGS. 9a to 9f, in another embodiment, the connection units 6, 6 'can also advantageously include, in addition to the connection modules 10, 10', corresponding magnetically shielded contact units 49, 49 'which are located in the corresponding connection housings 8, 8 'above and / or below the stack of connection modules 10, 10', each contact unit comprising an insulating housing 52, 52 'and one or a plurality of contacts 51, 51' which are mounted in the housing and are carried in order to form units which can be inserted into corresponding cavities 52, 52 'of the connection unit housings 8, 8'. The insertion of the magnetically shielded contact units 49, 49 'in the connection housings 8, 8' above (or below) the stack of connection modules 10, 10 'enables the efficient use of the volume that is between the flat connection module and the curved outer shape of the substantially cylindrical connector 2, 2 'is available.
The insulative housings 52, 52 'may advantageously have generally cylindrical shapes that are arranged for insertion into a cylindrical or substantially cylindrical magnetic shield shell 50 when the connectors 2, 2' are mated. The contacts may advantageously comprise mating receptacle 51 and pin contact portions 51 'on respective connectors 2, 2'.
The shield shell 50 may advantageously comprise a magnetic shield of mu-metal wrapped around both the female and female housings of the mating pair of contact units. In order to achieve proper shielding effectiveness, a length to diameter ratio of at least 3: 1 can be provided for the shell. For example, in one implementation example, this can be done by welding a thin sheet of mu-metal (0.004 to 0.014 ") to form a tube about 50 to 125 mm in length and about 13 to 20 mm in diameter.
This embodiment advantageously shields only those specific conductors which generate stray magnetic fields inside the connector or which are sensitive to magnetic fields, while the rest of the conductors remain unshielded, and enables a very compact connector system which at the same time has a high shielding effectiveness where necessary. This is particularly useful, for example, in medical applications, for example in connection catheters, for example for cardiac mapping, which can be implemented in magnetic resonance imaging (MRI) environments that are exposed to strong magnetic fields.
List of the reference symbols used
(Female) connector 2
Sheath 4 cable outlet guide 28 cable outlet end 29 plug-in interface 30 inner shells 32 locking projection 39a locking rib 41a outer shell 34, 36 locking ring 34 at the cable end locking ring 36 at the mating end connection unit 6 plug-in interface 31 housing 8 sheath positioning / locking elements 39a, 39b module receiving cavity 37 side wall 46 guide element 14a Latching element 16a shielded contact unit receiving cavity 52 power contacts 21 receiving contact 21a magnetically shielded contact unit 49 insulating housing 52 contacts 51 connection module 10 receiving slot 11 contacts 18 contact rows 19a, 19b plug contact section 38 connecting section 40 free end 43 connection module housing 20 first and second housing sections 20a, 20b, 20c, 20d Inner surface 45 Outer surface 47 Wiring board receiving cavity 42 Magnetic shield 22 Snap-in elements nt 16b guide element 14b connecting plate 12 wire connecting surfaces 24 contact surfaces 25 electrical / electronic components 26 locking recess 41b
Mating (housed) connector 2 '
Jacket 4 'plug-in interface 30' front plate locking ring 34 'rear plate locking ring 36' connection unit 6 'plug-in interface 31' housing 8 'module receiving cavity 37' front wall 47 'side wall 46' guide element 14a 'shielded contact unit receiving cavity 52' power contacts 21 'pin contact 21a 'Magnetically shielded contact unit 49' Insulating housing 52 'Contacts 51' Connection module 10 ', 10' 'Contacts 18' Connection plate 13 Contact surfaces 15 Front edge 17 Wire connection surfaces 24 Plug direction A Outer diameter D Height H Connection module width W Connection module

权利要求:
Claims (24)
[1]
1. A pluggable, high-density electrical connector (2) comprising a jacket (4) and a connector unit (6) mounted within the jacket, the connector unit comprising a housing (8) with a module receiving cavity (37), which is formed within the connection unit housing (8), and comprises a plurality of connection modules (10) which are inserted insertably in the module receiving cavity (37) in a stacked arrangement, each connection module having a plurality of contacts (18), which in a dielectric terminal module housing (20), and a connection plate (12) connected to the contacts (18), the connector having a number of electrical contacts exceeding sixty and a contact density at a mating interface (31) of the Connector of at least forty contacts per square centimeter, each connection module having a ratio of width W to height H, W / H, of greater than three, wherein di e contacts (18) of each connection module (10) at a first end comprise spring plug contact sections (38) which are arranged in two rows (19a, 19b) which form a receiving slot (11) which is designed to accommodate a received contact arrangement mating connector (2 ') therein, the contacts (18) of each connection module (10) further comprising connection portions (40) at a second end distal from the first end, which connect to contact surfaces (25) on the connection plate (12) are.
[2]
2. Connector according to claim 1, wherein the contact surfaces (25) are arranged on the connecting plate (12) at a front edge (27) and wherein the connecting plate can be inserted between the connecting sections (40) of the contacts (18) of one of the connection modules (10) is, for the electrical interconnection of the contact surfaces with the connecting sections.
[3]
3. A connector according to claim 1 or 2, wherein the connection plate comprises wire connection surfaces (24) arranged in at least two or more rows and at least five or more columns on either side of the connection plate.
[4]
4. A connector according to claim 3, wherein the wire connection surfaces (24) are arranged in at least three or more rows and at least eight or more columns on either side of the connection plate.
[5]
5. A connector according to any one of claims 2 to 4, wherein the connection plate (12) comprises electrical components (26) for filtering signals or providing signal processing functions, which are connected to one or more electrical circuit traces which interconnect the contact surfaces with the wire connection surfaces.
[6]
6. Connector according to one of claims 1 to 5, wherein each connection module (10) comprises insertion guide elements (14b) which cooperate with supplementary guide elements (14a) in the module receiving cavity (37) of the connection unit housing (8) for the insertion of each connection module in the connection unit housing (8) at a defined plane in the stack of the plurality of connection modules.
[7]
7. Connector according to claim 6, wherein the insertion guide element (14b) on each connection module is in the form of an axially extending projection or bead which is inserted into a corresponding complementary, axially extending recess or groove in a side wall (46) of the module receiving cavity ( 37) is included.
[8]
8. Connector according to claim 6 or 7, wherein each connection module comprises at least one locking element (16b) on a laterally smaller side (44) of the connection module housing, which is connected to at least one additional latching element (16a) in the side wall (46) of the module receiving cavity ( 37) clicks into place.
[9]
9. Connector according to one of claims 6 to 8, wherein the guide elements (14a) on the connection unit housing (8) and the insertion guide elements (14b) on each connection module (10) are designed to facilitate the insertion of the plurality of connection modules into the connection unit housing (8 ) in an axial direction (A) corresponding to a mating direction of the connector with a mating connector, and to be stacked on top of each other.
[10]
A connector according to any one of claims 1 to 9, wherein the connector comprises a number of electrical contacts in excess of one hundred and a contact density at a mating interface (31) of the connector of at least fifty contacts per square centimeter.
[11]
11. Connector according to one of claims 1 to 10, further comprising power contacts (21) which are suitable for electrical power supply, are positioned above and / or below the stack of modules and are mounted directly in the connection unit housing (8) of the connection unit.
[12]
12. Connector according to claim 11, wherein the power contacts (21) are receiving contacts.
[13]
13. Connector according to one of claims 1 to 12, wherein at least one of the connection modules (10) comprises a magnetic shield (22) which surrounds the connection module housing (20).
[14]
14. Connector according to one of claims 1 to 13, further comprising a magnetically shielded contact unit (49) which is mounted in the connection unit housing (8) above and / or below the stack of connection modules (10), the contact unit being a magnetic shielding sleeve (50), an insulating housing (52) which can be inserted into the magnetic shielding shell, and comprises one or a plurality of contacts (51) which are mounted and stored in the insulating housing, the magnetically shielded contact unit being insertable into a corresponding one Cavity (52) of the connection unit housing (8) is mounted above and / or below the stack of connection modules (10).
[15]
15. The connector of claim 14, wherein the magnetic shield shell (50) has a generally cylindrical shape.
[16]
16. The connector of claim 15, wherein the magnetic shield shell (50) has a length to diameter ratio of at least three.
[17]
17. A high density pluggable electrical connector system comprising the connector (2) of any preceding claim and a mating connector (2 ') pluggable to the connector (2) and separable from the connector (2), wherein the mating connector comprises a housing (8 ') and a plurality of terminal modules (10') mounted in a stacked arrangement in the housing (8 '), each terminal module comprising a connection plate (13) having a plurality of contact surfaces (15) which are arranged in a juxtaposed manner along a front edge (17) of the connection plate for pluggable connection with a corresponding plurality of contacts (18) of the connection modules of the connector.
[18]
18. Connector system according to claim 17, wherein the mating connector (2 ') comprises a jacket (4') and a connection unit (6 ') which is mounted within the jacket, the connection unit comprising the housing (8') with a module receptacle. A cavity (37 ') which is formed within the housing, wherein the plurality of connection modules (10') can be inserted into the module receiving cavity (37 ').
[19]
19. Connector system according to claim 18, wherein each connection module of the mating connector (2 ') consists of a connection plate (13).
[20]
20. The connector system of any one of claims 17 to 19, wherein the connection plate of the mating connector comprises wire connection surfaces (24) arranged in at least two or more rows and at least five or more columns on either side of the connection plate.
[21]
The connector system of claim 20, wherein the wire connection surfaces (24) of the mating connector are arranged in at least three or more rows and at least eight or more columns on either side of the connection plate.
[22]
22. Connector system according to one of claims 18 to 21, wherein the mating connector further comprises power contacts (21 ') which are suitable for electrical power supply, are positioned above and / or below the stack of modules and are directly in the housing (8') the connection unit (6 ') of the mating connector are mounted.
[23]
23. The connector system of claim 22, wherein the power contacts (21 ') of the mating connector are pin contacts.
[24]
24. Connector system according to one of claims 17 to 23, with a connector according to one of claims 14 to 16, wherein the mating connector further comprises a contact unit (49 ') in the housing (8') of the connection unit (6 ') and / or is mounted under the stack of connection modules (10 '), the contact unit comprising an insulating housing (52') which can be inserted into the magnetic shielding sleeve (50) and one or a plurality of contacts (51 '), which are mounted and stored in the insulating housing, wherein the contact unit can be inserted into a corresponding cavity (52 ') of the housing (8') of the connection unit (6 ') above and / or below the stack of connection modules (10').

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同族专利:

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公开号 | 公开日

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GB202018158D0|2021-01-06|

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DE212019000285U1|2021-01-22|

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WO2019219847A1|2019-11-21|

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US20210226376A1|2021-07-22|

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CN112292787A|2021-01-29|

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GB2587992A|2021-04-14|

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法律状态:

优先权:

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申请号 | 申请日 | 专利标题

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US201862672242P| true| 2018-05-16|2018-05-16|

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EP18172519|2018-05-16|

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PCT/EP2019/062686|WO2019219847A1|2018-05-16|2019-05-16|High density connector|

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