JP7233952B2 - coaxial connector - Google Patents

Description

background

[0001] Unless otherwise indicated herein, the material discussed in this section is not prior art to the claims within this application and is not admitted to be prior art by virtue of its inclusion in this section.

[0002] Coaxial connectors can be used in industrial applications to connect coaxial cables that transmit data. A coaxial connector may include an outer conductor contact and an inner conductor contact. A coaxial connector may be mechanically coupled to another coaxial connector. A coaxial connector may have a male connector component and a female connector component that mate to form a mated pair. Male connector components are sometimes called plugs or pins, and female connector components are sometimes called jacks or sockets. A pair of coaxial connectors may be coupled or mated by threading, bayonet coupling, or snap coupling.

overview

[0003] One embodiment of the invention is a connector effective for connecting coaxial contacts. A connector may comprise a female component. A female component may include a female housing. A female component may include an outer socket body within a female housing. The female component may include an outer spring within the outer socket body. The female component may include an outer piston within an outer socket. The outer piston can be a cylindrical tube segment having an inner surface and an outer surface. The outer piston can have a first piston end and a second piston end. The first piston end may have a flat surface that is on a plane essentially perpendicular to the inner and outer surfaces. The first piston end may include dimples protruding from a planar surface of the first piston end. The second piston end may have a flat inclined surface that is not in a plane essentially perpendicular to the inner and outer surfaces. A second piston end may contact an end of the outer spring. The female component is effective to conduct electricity and may include a central contact within the outer spring and outer piston. The female component may include a first insulator between the center contact and the outer spring. A connector may comprise a male component. A male component may include a male housing. The male component may include an outer pin within the male housing. The male component is effective to conduct electricity and may include a central pin within the outer pins. The male component may include a second insulator between the central pin and the outer pins. The first end of the female housing may be configured to mate with the first end of the male housing. The outer socket may be configured to mate with the outer pin. The outer pin may be configured to engage the outer piston. The outer piston may be configured to bring the center contact into contact with the center pin when engaging the outer piston.

[0004] Another embodiment of the invention includes a system for contacting a coaxial contact. The system can include a receptacle. The receptacle can include at least one female component. At least one female component may include a female housing. A female component may include an outer socket body within a female housing. The female component may include an outer spring within the outer socket body. The female component may include an outer piston within an outer socket. The outer piston can be a cylindrical tube segment having an inner surface and an outer surface. The outer piston can have a first piston end and a second piston end. The first piston end may have a flat surface that is on a plane essentially perpendicular to the inner and outer surfaces. The first piston end may include a dimple protruding from the planar surface of the first piston end. The second piston end may have a flat inclined surface that is not in a plane essentially perpendicular to the inner and outer surfaces. A second piston end may contact an end of the outer spring. The female component is effective to conduct electricity and may include a central contact within the outer spring and outer piston. The female component may include a first insulator between the center contact and the outer spring. The system may include a plug. A plug may include at least one male component. At least one male component may include a male housing. The male component may include an outer pin within the male housing. The male component is effective to conduct electricity and may include a central pin within the outer pins. The male component may include a second insulator between the central pin and the outer pins. A first end of each female housing may be configured to mate with a first end of a respective male housing. The outer socket may be configured to mate with the outer pin. The outer pin may be configured to engage the outer piston. The outer piston may be configured to bring the central contact into contact with the central pin when engaging the outer pin.

[0005] Another embodiment of the invention is a method for connecting to a coaxial contact. The method may comprise aligning a first end of the female housing of the female component and a first end of the male housing of the male component. A female component may include a female housing. A female component may include an outer socket body within a female housing. The female component may include an outer spring within the outer socket body. The female component may include an outer piston within an outer socket. The outer piston can be a cylindrical tube segment having an inner surface and an outer surface. The outer piston can have a first piston end and a second piston end. The first piston end may have a flat surface that is on a plane essentially perpendicular to the inner and outer surfaces. The first piston end may include a dimple protruding from the planar surface of the first piston end. The second piston end may have a flat inclined surface that is not in a plane essentially perpendicular to the inner and outer surfaces. A second piston end may contact an end of the outer spring. The female component may include a central contact effective to conduct electricity. A central contact can be in the outer spring and the outer piston. The female component may include a first insulator between the center contact and the outer spring. A male component may include a male housing. The male component may include an outer pin within the male housing. A male component may include a central pin effective to conduct electricity. The central pin can be within the outer pin. The male component may include a second insulator between the central pin and the outer pins. The method may comprise coupling the first end of the female housing with the first end of the male housing. The method may comprise coupling the outer socket with the outer pin. The method may comprise contacting the outer pin with the outer piston. The method may comprise contacting the center contact with the center pin.

[0006] The foregoing summary is for illustrative purposes only and is not intended to be limiting in any way. In addition to the exemplary aspects, embodiments, and features described above, further aspects, embodiments, and features will become apparent by reference to the drawings and detailed description that follows.

[0007] The foregoing and other features of the present disclosure will become more fully apparent from the following description and appended claims, taken in conjunction with the accompanying drawings. An understanding that these drawings depict only some embodiments in accordance with the present disclosure is therefore not to be considered limiting of its scope, and the present disclosure is, through the use of the accompanying drawings, an additional will be described with specificity and detail.

1 is a side cutaway view of a female component of a coaxial connector and a male component of a coaxial connector; FIG. 2A is a side perspective view of the outer piston of the female component of the coaxial connector; FIG. FIG. 2B is a side perspective view of the dimple of the outer piston of the female component of the coaxial connector; 3 is a side cutaway view of the female component of the coaxial connector mated to the male component of the coaxial connector; FIG. 4 is a side cutaway view of the female component of the coaxial connector mated to the male component of the coaxial connector; FIG. 5 is a side cutaway view of the female component of the coaxial connector mated to the male component of the coaxial connector; FIG. FIG. 6A is a side perspective view of the plug and receptacle; FIG. 6B is a side perspective view of the plug mated with the receptacle; 7 is a side perspective view of a medical test device utilizing multiple plugs and receptacles; FIG. FIG. 8 is a longitudinal cutaway view of a plug and receptacle with a clamshell; FIG. 9 is a short cutaway view of a plug and receptacle with a clamshell. FIG. 10 illustrates a flow diagram for an exemplary process for connecting coaxial contacts, all constructed in accordance with at least some embodiments described herein.

detailed description

[0009] In the following detailed description, reference is made to the accompanying drawings, which form a part thereof. In the drawings, similar symbols typically identify similar components, unless context dictates otherwise. The illustrative embodiments described in the detailed description, drawings, and claims are not meant to be limiting. Other embodiments may be utilized and other changes may be made without departing from the spirit or scope of the subject matter presented herein. As generally described herein and illustrated in the drawings, aspects of the present disclosure can be arranged, interchanged, combined, separated, and designed in a variety of different configurations and It will be readily understood that all are expressly contemplated here.

[0010] FIG. 1 is a side cutaway view of a female component of a coaxial connector and a male component of a coaxial connector, constructed in accordance with at least some embodiments described herein; System 100 may include coaxial connector 10 . Coaxial connector 10 may include female connector 120 and male connector 160 . Female connector 120 may include female component 20 and female housing 55 . Female component 20 may include insulator 25 , outer spring 30 , outer piston 35 , outer socket body 40 , central contact 45 effective to conduct electricity, and inner spring 50 . Outer socket body 40 may reside within female housing 55 . Outer spring 30 and outer piston 35 may reside within outer socket body 40 . Central contact 45 may be in outer spring 30 and outer piston 35 . Insulator 25 may be between center contact 45 and outer spring 30 . Female housing 55 may include a first end 52 and a second end 53 . Male connector 160 may include male component 60 and male housing 80 . Male component 60 may include an outer pin 65, an insulator 70, and a central pin 75 effective to conduct electricity. Insulator 70 may be between central pin 75 and outer pin 65 . Male housing 80 may include a first end 82 and a second end 83 . First end 52 of female housing 55 may be configured to mate with first end 82 of male housing 80 . First end 52 of female housing 55 may be aligned with first end 82 of male housing 80 , and first end 52 of female housing 55 fits within first end 82 of male housing 80 . obtain. First end 52 of female housing 55 may be configured to facilitate mating of central contact 45 of outer socket body 40 of female component 20 with outer pin 65 of male component 60 . Outer pin 65 can fit within outer socket body 40 and outer pin 65 can engage outer piston 35 when female component 20 and male component 60 are mated. The outer socket body 40 and outer piston 35 may be non-magnetic and coated with a nickel-phosphorus thin film plating or a ternary alloy thin film plating of copper, tin and zinc. All metal components of female component 20 may be non-magnetic. Outer pin 65 may engage outer piston 35 and compress outer spring 30 when female component 20 and male component 60 are mated. All metal components of male component 60 may be non-magnetic. Spring 30 may be beryllium copper and may be non-magnetic. When the male component 60 and female component 20 are mated, the outer piston 35 can move with the compressed spring 30 exposing the central contact 45 . The central contact 45 of the female component 20 can fit within the outer pin 65 and engage the central pin 75 of the male component 60 . When center contact 45 engages center pin 75, inner spring 50 may compress. The central pin 75 can be non-magnetic and can be covered with a nickel-phosphorus thin film plating or a ternary alloy thin film plating of copper, tin and zinc. Outer piston 35 may be configured to engage outer pin 65 to facilitate mating of center contact 45 of female component 20 with center pin 75 of male component 60, as described in more detail below.

[0011] Fig. 2A is a side perspective view of an outer piston of a female component of a coaxial connector, constructed in accordance with at least some embodiments described herein; FIG. 2B is a side perspective view of an outer piston dimple of a female component of a coaxial connector, constructed in accordance with at least some embodiments described herein; Those components in FIGS. 2A and 2B that are labeled similarly to the components in FIG. 1 will not be described again for purposes of brevity.

[0012] The outer piston 35 may be a hollow cylindrical tube segment having a first end 205, a second end 210, an outer surface 212a, and an inner surface 212b. The outer piston can be a copper alloy such as brass or bronze. Inner surface 212 b or outer piston 35 may define a channel 215 through outer piston 35 from first end 205 to second end 210 . First end 205 of outer piston 35 may have a flat surface 220 on a plane essentially perpendicular to outer surface 212a and inner surface 212b. A second end 210 of outer piston 35 may have a flat angled surface 222 . The angled surface 222 may not lie on a plane essentially perpendicular to the outer surface 212 a and the inner surface 212 b and may be angled from the planar surface 220 of the first end 205 . Due to the angled surface 222, the outer piston 35 is not uniform in length, ranging from the longest length at 214a to the shortest length at 214b. A planar surface 220 of first end 205 may include dimples 225 protruding from planar surface 220 . Dimple 225 may be a semi-cylinder, bisected through the circular face of the cylinder, having a flat side 230 and a curved side 235 . A flat side 230 of the dimple 225 may abut the flat surface 220 of the outer piston 35 and a curved side 235 may protrude from the flat surface 220 of the outer piston 35 .

[0013] FIG. 3 is a side cutaway view of a female component of a coaxial connector coupled to a male component of a coaxial connector, constructed in accordance with at least some embodiments described herein; Those components in FIG. 3, which are numbered similarly to the components in FIGS. 1-2, are not described again for purposes of brevity.

[0014] When male component 60 and female component 20 are mated, outer pin 65 of male component 60 may fit within outer socket body 40 of female component 20 . Outer pin 65 may engage and connect to dimple 225 of outer piston 35 . Dimples 225 may reduce the contact area between outer piston 35 and outer pin 65 . Dimples 225 may reduce contact stress between outer piston 35 and outer pin 65 . Dimples 225 may optimize Hertzian stress during contact between outer piston 35 and outer pin 65 .

Outer pin 65 may engage dimple 225 of outer piston 35 to compress outer spring 30 . Outer piston 35 can move with spring 30 compressed to expose central contact 45 . The central contact 45 of the female component 20 can fit within the outer pin 65 and engage the central pin 75 of the male component 60 . When compressed, the outer spring 30 can apply a force 310 to the angled surface 222 of the outer piston 35 at the longest side length 214a and apply a second force 320 to the angled surface 222 of the outer piston 35 at the shortest side length 214b. can be applied to Force 310 is greater than force 320 due to spring 30 being more compressed by angled surface 222 of outer piston 35 at longest side length 214a than by angled surface 222 of outer piston 35 at shortest side length 214b. can grow. Force 310 greater than force 320 may then apply force 330 toward outer socket body 40 at the end of longest side length 214 a adjacent inclined surface 222 . Force 310 greater than force 320 may then also apply force 340 toward outer socket body 40 adjacent flat surface 220 at the end of shortest side length 214b. Forces 330 and 340 may allow outer piston 35 to slide within outer socket body 40 with low contact stress. Outer piston 35 engaging outer pin 65 may facilitate contact between center contact 45 of female component 20 and center pin 75 of male component 60 .

[0016] FIG. 4 is a side cutaway view of a female component of a coaxial connector coupled to a male component of a coaxial connector, constructed in accordance with at least some embodiments described herein; Those components in FIG. 4, which are numbered similarly to the components in FIGS. 1-3, are not described again for purposes of brevity.

First end 52 of female housing 55 may be configured to mate with first end 82 of male housing 80 . First end 52 of female housing 55 can fit within first end 82 of male housing 80 to facilitate mating contact with outer pin 65 of male component 60 of outer socket body 40 of female component 20 . can be configured to The first end 52 of the female housing 55 and the first end 82 of the male housing 80 may be offset such that the first end 52 of the female housing 55 and the first end 82 of the male housing 80 are arranged side by side. may contain a gap between Outer pins 65 of male component 60 may fit within outer socket body 40 of female component 20 when male component 60 and female component 20 are mated. Outer pin 65 may engage and connect with dimple 225 of outer piston 35 . Outer pin 65 may engage dimple 225 of outer piston 35 to compress outer spring 30 . Outer piston 35 can move with spring 30 compressed to expose central contact 45 . The central contact 45 of the female component 20 can fit within the outer pin 65 and engage the central pin 75 of the male component 60 .

[0018] As explained above, the outer spring 30, upon compression, can apply a force to the outer piston 35, allowing the outer piston 35 to slide within the outer socket body 40 with low contact stress. can make it possible. The outer piston 35 engaged with the outer pin 65 can facilitate contact between the center contact 45 of the female component 20 and the center pin 75 of the male component 60, such as coupling at an oblique angle. Misalignment between pin 65 and outer socket body 40 may be compensated for. The outer piston 35 can compensate for a deviation of the central contact 45 of the female component 20 and the central pin 75 of the male component 60 of +/−0.3 mm in the axial (X, Y) direction.

[0019] FIG. 5 is a side cutaway view of a female component of a coaxial connector coupled to a male component of a coaxial connector, constructed in accordance with at least some embodiments described herein; Those components in FIG. 5 that are numbered similarly to the components in FIGS. 1-4 are not described again for purposes of brevity.

First end 52 of female housing 55 may be configured to mate with first end 82 of male housing 80 . First end 52 of female housing 55 can fit within first end 82 of male housing 80 to facilitate mating of outer socket body 40 of female component 20 with outer pin 65 of male component 60 . can be configured as First end 52 of female housing 55 and first end 82 of male housing 80 may be offset and may include a gap 510 between the ends of first end 52 of female housing 55 and male housing 80 . unknown. Outer pins 65 of male component 60 may fit within outer socket body 40 of female component 20 when male component 60 and female component 20 are mated. Outer pin 65 may engage and contact dimple 225 of outer piston 35 . Outer pin 65 may engage dimple 225 of outer piston 35 to compress outer spring 30 . Outer piston 35 may move with compressed spring 30 to expose central contact 45 . The central contact 45 of the female component 20 can fit within the outer pin 65 and engage the central pin 75 of the male component 60 .

[0021] As explained above, the outer spring 30, upon compression, can apply a force to the outer piston 35, allowing the outer piston 35 to slide within the outer socket body 40 with low contact stress. can make it possible. Outer piston 35 engaging outer pin 65 may facilitate contact between center contact 45 of female component 20 and center pin 75 of male component 60 . Outer piston 35 may compensate for misalignment between outer pin 65 and outer socket body 40 . Outer piston 35 may compensate for a misalignment gap between first end 52 of female housing 55 and male housing 80 of up to 1 mm.

[0022] FIG. 6A is a side perspective view of a plug and receptacle configured in accordance with at least some embodiments described herein; FIG. 6B is a side perspective view of a plug mated with a receptacle, constructed in accordance with at least some embodiments described herein; Those components in FIGS. 6A and 6B, which are numbered similarly to the components of FIGS. 1-5, are not described again for purposes of brevity.

System 600 may include plug 610 and receptacle 620 . In embodiments, plug 610 may include multiple male components 60 and receptacle 620 may include multiple female components 20 . Plug 610 may be configured to mate with receptacle 620 such that each male component 60 mates with a respective female component 20 within receptacle 620 . Plug 610 and receptacle 620 are components to the coaxial connector. Plug 610 and receptacle 620 are water resistant and can be used in industry. All metal components of plug 610 and receptacle 620 may be non-magnetic. Plug 610 and receptacle 620 may be used in medical equipment, such as magnetic resonance imaging (MRI) equipment. Plug 610 and receptacle 620 may also be used as catheter or endoscope connectors for medical devices.

[0024] FIG. 7 is a side perspective view of a medical test device utilizing multiple plugs and receptacles, constructed in accordance with at least some embodiments described herein; Those components in FIG. 7, which are numbered similarly to the components in FIGS. 1-6, are not described again for the sake of brevity.

[0025] Medical test apparatus 710 may include a cover 720 and a base 730. As shown in FIG. Cover 720 may include a plurality of male connectors 160 with male components 60 . The base may include multiple female connectors 120 with female components 20 . Male connector 160 of cover 720 may mate with female connector 120 of base 730 .

[0026] FIG. 8 is a longitudinal cutaway view of a plug and receptacle having a clamshell, constructed in accordance with at least some embodiments described herein; Those components in FIG. 8 that are numbered similarly to the components in FIGS. 1-7 are not described again for purposes of brevity.

[0027] System 800 may include a plug 810 having a clamshell 815 and a receptacle 820. As shown in FIG. In embodiments, the plug 810 may include a clamshell 815 and multiple male components 60 . Clamshell 815 may be a watertight wall for plug 810 . Receptacle 820 may include multiple female components 20 . Plug 810 may be configured to mate with receptacle 820 such that each male component 60 mates with a respective female component 20 within receptacle 820 . Plug 810 and receptacle 820 can be components to a coaxial connector.

[0028] FIG. 9 is a short cutaway view of a plug and receptacle having a clamshell, constructed in accordance with at least some embodiments described herein; Those components in FIG. 9 that are numbered similarly to the components in FIGS. 1-8 are not described again for purposes of brevity.

[0029] System 900 may include a plug 810 having a clamshell 815 and a receptacle 820. As shown in FIG. Plug 810 may include clamshell 815 , locking lever 910 and multiple male components 60 . Receptacle 820 may include protrusion 920 and multiple female components 20 . Plug 810 is coupled to receptacle 820 such that locking lever 910 clips projection 920 to lock plug 810 to receptacle 820 and each male component 60 mates with a respective female component 20 within receptacle 820 . can be configured to

[0030] Apparatus according to the present disclosure may enable mating of coaxial contacts through over 100,000 mating cycles. A device according to the present disclosure may provide a spring-loaded coaxial contact capable of compensating for a misalignment between the male and female components of +/−0.3 mm in the axial direction (X,Y). A device according to the present disclosure can provide a spring-loaded coaxial contact that can compensate for offset gaps between the ends of the female housing and the male housing of up to 1 mm. Devices according to the present disclosure may provide plugs and receptacles for use with medical equipment, such as magnetic resonance imaging (MRI) equipment.

[0031] FIG. 10 illustrates a flow diagram for an exemplary process for connecting coaxial contacts, configured in accordance with at least some embodiments described herein. An exemplary process may include one or more acts, actions, or functions as illustrated by one or more of blocks S2, S4, S6, S8, and/or S10. Although shown as separate blocks, various blocks may be divided into additional blocks, combined into fewer blocks, or deleted, depending on the desired implementation.

[0032] The process proceeds to Block S2, "Align the first end of the female housing of the female component to the first end of the male housing of the male component, wherein the female component includes a female housing and an outer housing within the female housing. A socket body, an outer spring within the outer socket body, and an outer piston within the outer socket, the outer piston being a cylindrical tube segment having an inner surface and an outer surface, the outer piston having a first piston end and a second piston end. , the first piston end having a flat surface that is on a plane essentially perpendicular to the inner and outer surfaces, the first piston end being the flat surface of the first piston end the second piston end having a flat inclined surface that is out of plane substantially perpendicular to the inner and outer surfaces, the second piston end contacting the end of the outer spring; a central contact within the outer spring and the outer piston effective to conduct electricity; a first insulator between the central contact and the outer spring; a housing, an outer pin within the male housing, a central pin within the outer pin effective to conduct electricity, and a second insulator between the central pin and the outer pin. At block S2, the first end of the female housing of the female component may be aligned with the first end of the male housing of the male component. The female components include a female housing, an outer socket body within the female housing, an outer spring within the outer socket body, an outer piston within the outer socket, a center contact, and a first contact between the center contact and the outer spring. and an insulator. The outer piston can be a cylindrical tube segment having an inner surface and an outer surface. The outer piston can have a first piston end and a second piston end. The first piston end may have a flat surface that is on a plane essentially perpendicular to the inner and outer surfaces. The first piston end may include a dimple protruding from the planar surface of the first piston end. The second piston end may have a flat inclined surface that is not in a plane essentially perpendicular to the inner and outer surfaces. A second piston end may contact an end of the outer spring. A center contact can be effective in conducting electricity. A central contact can be in the outer spring and the outer piston. The male component may include a male housing, an outer pin within the male housing, a central pin, and a second insulator between the central pin and the outer pin. A central pin can be effective in conducting electricity. The central pin can be within the outer pin.

[0033] Processing may continue from Block S2 to Block S4, "Coupling first end of female housing to first end of male housing." At block S4, the first end of the female housing may be coupled to the first end of the male housing. The first end of the female housing may be configured to mate with the first end of the male housing.

[0034] Processing may continue from Block S4 to Block S6, "Coupling Outer Socket to Outer Pin." At block S6, the outer socket of the female component may mate with the outer pin of the male component. The outer socket of the female component may be configured to mate with the outer pin of the male component.

[0035] Processing may continue from Block S6 to Block S8, "OUTER PIN ENGAGES OUTER PISTON." At block S8, the outer pin of the male component may engage the outer piston of the female component. An outer pin of the male component may be configured to engage an outer piston of the female component.

[0036] Processing may continue from Block S8 to Block S10, "CENTER CONTACT CONTACTS CENTER PIN." At block S10, the center contact of the female component may contact the center pin of the male component. The outer piston may be configured to bring the central contact into contact with the central pin when engaging the outer pin.

[0037] While various aspects and embodiments have been disclosed herein, other aspects and embodiments will be apparent to those skilled in the art. The various aspects and embodiments disclosed herein are intended to be illustrative and not limiting, with the true scope and spirit indicated by the following claims.

Claims (20)

A connector for effectively connecting to coaxial contacts, comprising:
a female component;
a male component, and
The female component is
a female housing;
an outer socket body within the female housing;
an outer spring within the outer socket body;
an outer piston within said outer socket body, wherein said outer piston is a cylindrical tube segment having an inner surface and an outer surface, said outer piston having a first piston end and a second piston end; The first piston end has a planar surface that is on a plane essentially perpendicular to said inner surface and said outer surface, said first piston end projecting from said planar surface of said first piston end. including a dimple, said second piston end having a flat inclined surface out of plane substantially perpendicular to said inner surface and said outer surface, said second piston end contacting an end of said outer spring; death,
a central contact in said outer spring and said outer piston effective to conduct electricity;
a first insulator between the central contact and the outer spring;
The male component is
a male housing;
an outer pin within the male housing;
a central pin within said outer pins effective to conduct electricity;
a second insulator between the central pin and the outer pin;
The first end of the female housing is configured to mate with the first end of the male housing, the outer socket is configured to mate with the outer pin, and the outer pin engages the outer piston. A connector configured for engagement, wherein the outer piston is configured to bring the central contact into contact with the central pin upon engagement with the outer pin. The dimple is semi-cylindrical and bisected through the circular face of the cylinder, the dimple including a flat side and a curved side, the flat side of the dimple being in contact with the flat surface of the first piston end. 2. The connector of claim 1, wherein adjacent, curved sides of said dimples project from said flat surface of said first piston end. 3. The connector of claim 2, wherein said dimple reduces the contact area between said first piston end of said outer piston and said outer pin. 3. The connector of claim 2, wherein said dimple reduces contact stress between said first piston end of said outer piston and said outer pin. 3. The method of claim 2, wherein the dimple optimizes Hertzian stress between the first piston end of the outer piston and the outer pin when the first piston end of the outer piston contacts the outer pin. Connector as described. 2. The connector of claim 1, wherein said outer socket body and said outer piston are non-magnetic. 2. The connector of claim 1, wherein said outer piston compensates for a misalignment of said central contact and said central pin of +/−0.3 mm axially. 2. The connector of claim 1, wherein the outer piston compensates for misalignment between the first end of the female component and the male housing of up to 1 mm. A system for connecting to coaxial contacts, comprising:
a receptacle including at least one female component;
a plug including at least one male component;
said at least one female component comprising:
a female housing;
an outer socket body within the female housing;
an outer spring within the outer socket body;
an outer piston within said outer socket body, wherein said outer piston is a cylindrical tube segment having an inner surface and an outer surface, said outer piston having a first piston end and a second piston end; The first piston end has a planar surface that is on a plane essentially perpendicular to said inner surface and said outer surface, said first piston end projecting from said planar surface of said first piston end. including a dimple, said second piston end having a flat inclined surface out of plane substantially perpendicular to said inner surface and said outer surface, said second piston end contacting an end of said outer spring; death,
a central contact in said outer spring and said outer piston effective to conduct electricity;
a first insulator between the central contact and the outer spring;
the at least one male component comprising:
a male housing;
an outer pin within the male housing;
a central pin within said outer pins effective to conduct electricity;
a second insulator between the central pin and the outer pin;
The first end of each female housing is configured to mate with the first end of the respective male housing, the outer socket is configured to mate with the outer pin, and the outer pin connects to the outer piston. and wherein the outer piston is configured to bring the central contact into contact with the central pin upon engagement with the outer pin. The dimple is semi-cylindrical and bisected through the circular face of the cylinder, the dimple including a flat side and a curved side, the flat side of the dimple being in contact with the flat surface of the first piston end. 10. The system of claim 9, wherein adjacent, curved sides of said dimples project from said flat surface of said first piston end. 11. The system of claim 10, wherein the dimple reduces contact area between the first piston end of the outer piston and the outer pin. 11. The system of claim 10, wherein said dimple reduces contact stress between said first piston end of said outer piston and said outer pin. 11. The dimple optimizes Hertzian stress between the first piston end of the outer piston and the outer pin when the first piston end of the outer piston contacts the outer pin. System as described. 10. The system of claim 9, wherein said outer socket body and said outer piston are non-magnetic and coated with a nickel-phosphorus thin film plating. 11. The system of claim 10, wherein the plug and receptacle are part of a magnetic resonance imaging (MRI) machine. 11. The system of claim 10, wherein the outer piston compensates for a deviation of the central contact and the central pin of +/−0.3 mm axially. 11. The system of claim 10, wherein the outer piston compensates for deviations between the first end of the female component and the male housing of up to 1 mm. Is there a way to connect coaxial contacts,
aligning the first end of the female housing of the female component with the first end of the male housing of the male component;
wherein said female component comprises:
a female housing;
an outer socket body within the female housing;
an outer spring within the outer socket body;
an outer piston within said outer socket body, said outer piston being a cylindrical tube segment having an inner surface and an outer surface; said outer piston having a first piston end and a second piston end; One piston end has a flat surface lying on a plane essentially perpendicular to said inner surface and said outer surface, and said first piston end has a dimple protruding from said first piston end flat surface. wherein said second piston end has a flat inclined surface that is not in a plane substantially perpendicular to said inner surface and said outer surface, said second piston end contacting an end of said outer spring , the outer piston, and
a central contact in said outer spring and said outer piston effective to conduct electricity;
a first insulator between the central contact and the outer spring;
The male component is
a male housing;
an outer pin within the male housing;
a central pin within said outer pins effective to conduct electricity;
a second insulator between the central pin and the outer pin;
coupling the first end of the female housing with the first end of the male housing;
coupling the outer socket with the outer pin;
contacting the outer pin with an outer piston;
contacting the center contact with the center pin;
and how to provide. 19. The method of claim 18, wherein the outer piston compensates for a deviation of the central contact and the central pin of +/−0.3 mm in the axial direction. 19. The method of claim 18, wherein the outer piston compensates for deviations between the first end of the female component and the male housing of up to 1 mm.

Images