KR940702273A - Fiber optic splicer with device for positioning the center of the fiber along the selected reference axis - Google Patents

Abstract

The present invention provides a positioning apparatus 20 for positioning a point on a cylindrical member having a small diameter such as optical fibers F1 and F2 along a reference axis R, R 'selected regardless of the outer diameter of the optical fiber. ¹ , 20 ² , 20 ³ ).

Description

Fiber optic splicer with device for positioning the center of the fiber along the selected reference axis

Since this is an open matter, no full text was included.

FIG. 21 is an exploded isometric view of a pair of positioning devices as shown in FIG. 1 used to form the fiber-optic connector according to the present invention, and FIG. 22 is an isometric view of the complete assembled connector of FIG. FIG. 23 is a plan view and a side cross-sectional view of a pair of positioning devices according to an embodiment of the present invention as shown in FIG. 17 used to form an optical fiber-optic fiber connector according to the present invention.

Claims (88)

A connector for positioning a first cylindrical member relative to a second cylindrical member, the connector comprising a first positioning device, a second positioning device, and a base, wherein the first positioning device is at least a first arm. First and second having at least first and second sidewalls cooperating to define a groove on the arm and the arms are aligned in an overlapping relationship and each arm can move from a first, closed position to a second, central position Arms, and means for biasing each of the arms toward the first closed position with a biasing force of approximately the same size and opposite direction, wherein the arms define a channel passing through the first reference axis in the closed position. And a first cylindrical member inserted into the inlet end of the channel so that the channel has an inlet end and an outlet end, and the axis of the cylindrical member is spaced apart from the first reference side. Each of the arms is aligned such that the selected point on the end face of the first member is displaced by contacting at least one of the arms so that the selected point is aligned with the first reference axis, the first and second arms and the first and second arms Continuous contact of the first member through the channel by moving the point on the end face of the first member by contact between the members against the biasing force toward a central position to maintain the point on the first reference axis in alignment. Responsive to axial movement, the first positioning device having at least first and second side walls with which at least a third arm cooperates to define a groove on the arm, the arms are aligned in an overlapping relationship, and each arm is Biasing the third and fourth arms toward the first closed position with first and third arms that are movable from the closed position to the second, central position, and with biasing forces of approximately equal magnitude and opposite directions; city Means for discharging, the third and fourth arms cooperate to define a channel passing through a second reference axis in the closed position, the channel having an inlet end and an outlet end, and a second cylindrical member The second cylindrical member inserted in the inlet end of the channel is spaced apart from the second reference axis by contact with at least one of the third and fourth arms so that the selected point on the end face of the second member Each of the third and fourth arms is aligned so that the third and fourth arms can be arranged in a line with the second reference axis, and a second reference is made to a point on the end face of the second member by contact between the third and fourth arms. Responsive to axial movement of the second member through the channel by moving against the bias force towards the center position to maintain the alignment with the axis, the outlet end of the first and second channels And one of the first and second arms and one of the third and fourth arms are mounted to the foundation such that the two reference axes are arranged to face each other and the second reference axis is aligned with the first reference axis. . The method of claim 1, wherein the first and second sidewalls in the first and third arms cooperate to define converging grooves in the first and third arms and are defined by a cooperative combination of the first and second arms. And wherein the shape of the channel defined by the cooperative combination of the channel and the third and fourth arms is each partially funneled over a predetermined portion of the axial length. The connector according to claim 2, wherein the surfaces of the second and fourth arms are flat. 3. The method of claim 2, wherein the second and fourth arms have at least first and second sidewalls, and the first and second sidewalls in the second and fourth arms define converging grooves in the second and fourth arms. Cooperate to define a channel in which the converging grooves in the first and second arms are fully funneled over a predetermined portion of the axial length, and the converging grooves in the third and fourth arms are also And cooperating to define a channel that is fully funneled over a selected portion of the axial length. The first and second arms of claim 1, wherein the first and second sidewalls in the first and third arms cooperate to define grooves in the first and third arms that are equal in width across the entire length. And cooperating to define channels having equal widths over the entire length, wherein the third and fourth arms cooperate to define channels having equal widths over the entire length. 6. The second and fourth arms of claim 5, wherein each of the second and fourth arms has at least first and second sidewalls therein, and the first and second sidewalls in the second and fourth arms have an equal width over the entire length. Cooperate to define a groove, the equal width groove in the first and second arms cooperate to define a channel having a rectangular cross section over a predetermined portion of the axial length, and the same width in the second and fourth arms Wherein the grooves also cooperate to define a channel having a rectangular cross section over a selected portion of the axial length. 7. The groove of claim 6, wherein the grooves in the first and third arms have respective sidewalls and each sidewall of the grooves in the second and fourth arms have edges, and the edges of the sidewalls in the first and second arms have first members. And the edges of the axial surfaces of the third and fourth arms contact the second member. 6. The method of claim 5, wherein the second and fourth arms have a plane and the grooves in the first and third arms each have edges with edges, and the edges of the sidewalls of the first arm contact the first member. And edges of the sidewall of the third arm are in contact with the second member. 2. The trough of claim 1 wherein each arm has a trough, wherein the trough in the first and second arms and the trough in the third and fourth arms are a cooperative combination of the first and second arms and the third and the third arm. 4 cooperate to define a guideway for guiding a member between the arms towards a corresponding channel defined by a cooperative combination of arms. The connector according to claim 9, wherein each of the guide paths has an axis spaced apart from a corresponding channel axis by a predetermined distance. The arm of claim 1, wherein the biasing means and a curved portion in each arm that generate a force on each arm to bias the arm toward the closed position when the arm is deflected by contact with the member. A connector comprising a thickness reduction. The connector according to claim 1, wherein the first arm, the second arm, and the third arm are mounted to the base portion. 13. The connector of claim 12, wherein the base and the arms are each made of a crystalline material. 2. A connector as claimed in claim 1, wherein said base and said arms are each made of a crystalline material. The method of claim 1, wherein each arm has a major surface connected to the first and second sidewalls and cooperating to define a groove in the arm, wherein the converging grooves defined in each arm are truncated V-shaped. Splicer. 5. A connector as claimed in claim 4, wherein first and third arms are mounted to the foundation. 17. The connector of claim 16, wherein said base portion and said arms are each made of a crystalline material. The arm of claim 4, wherein the biasing means defines a curvature in each arm that generates a force on each arm to bias each arm toward a closed position when each arm is deflected by contact with the member. And a thickness reducing part. 19. The connector of claim 18, wherein said base portion and said arms are each made of a crystalline material. 5. The method of claim 4, wherein each arm has a major surface connected to the first and second sidewalls and cooperating to define a groove in the arm, wherein the converging grooves defined in each arm are truncated V-shaped. Splicer. 5. The trough of claim 4 wherein each arm has a trough therein and each trough is disposed in the same arm a predetermined distance behind a groove in one arm, and in the closed position the trough and the second arm. The troughs in the third and fourth arms cooperate to define a guideway for guiding the member toward the corresponding channel defined by the cooperative combination of the first and second arms and the cooperative combination of the third and fourth arms. Connector made. 22. A connector according to claim 21, wherein the guide path has an axis spaced apart from the channel axis by a predetermined distance. 5. The connector according to claim 4, wherein said first, second, third, and fourth arms and said base portion are disposed in a housing. The connector according to claim 1, wherein said first, second, third, and fourth arms and said base portion are disposed in a housing. 2. The apparatus of claim 1, wherein the first and second cylindrical members each comprise an optical fiber having ends, and wherein the first and second optical fibers each have a predetermined cap defined between the ends of the optical fiber. 2 A positioner, characterized in that the position is set by the positioning device. The optical fiber according to claim 1, wherein the first and second cylindrical members are optical fibers that operate to transmit light, and when the first and second positioning devices are axially separated for a gap, the gap is in a straight line. And an optical element having a predetermined axis size along an aligned reference axis, wherein the connector further comprises an optical element disposed in a gap of the first and second positioning devices. 27. A connector as claimed in claim 26 wherein said optical element comprises a filter. 28. The connector of claim 27, wherein said first, second, third, fourth arm, base, filter, and top cap are disposed in a housing. The connector according to claim 28, wherein said first, second, third, and fourth arms and said base portion are disposed in a housing. 27. The attenuator of claim 26, wherein the optical element has an attenuator having a predetermined axis size and a predetermined light density to act to attenuate a predetermined amount of light of a predetermined wavelength transmitted between the first and second optical fibers. A connector, characterized in that it comprises. 31. The connector of claim 30, wherein said first, second, third, fourth arm, base, filter, and top cap are disposed in a housing. 32. A connector according to claim 31, wherein said first, second, third, and fourth arms and said base portion are disposed in a housing. 27. The system of claim 26, wherein the optical element comprises an attenuator, wherein the predetermined wavelength delivered by the attenuator between the first and second optical fibers is attenuated by a first predetermined amount by the action of the first region of the attenuator, And define a first region by a predetermined light density and a first axis thickness and a second region by a predetermined light density and a second axis thickness to be attenuated by a second predetermined amount by the action of the second region. Connector made. 34. The connector of claim 33, wherein the attenuator is cascaded to define first and second regions. 34. The connector of claim 33, wherein the attenuator is formed of counterbored blocks to define first and second regions. 34. The connector of claim 33, wherein the first, second, third, fourth arm, base, filter and top cap are disposed in a housing. 35. A connector according to claim 34, wherein said first, second, third, and fourth arms and said base portion are disposed in a housing. 5. The apparatus of claim 4, wherein the first and second cylindrical members each comprise an optical fiber having ends, and wherein the first and second optical fibers each have a predetermined gap defined between the ends of the optical fiber. 2 A positioner, characterized in that the position is set by the positioning device. The optical fiber according to claim 4, wherein the first and second cylindrical members are optical fibers that operate to transmit light, and when the first and second positioning devices are axially separated for a gap, the gap is in a straight line. And an optical element having a predetermined axis size along an aligned reference axis, wherein the connector further comprises an optical element disposed in a gap of the first and second positioning devices. 40. A connector as claimed in claim 39 wherein said optical element comprises a filter. 41. The connector of claim 40, wherein the first, second, third, fourth arm, base, filter and top cap are disposed in a housing. 42. A connector according to claim 41, wherein said first, second, third, and fourth arms and said base portion are disposed in a housing. 40. The apparatus of claim 39, wherein the optical element comprises an attenuator having a predetermined axis size and a predetermined light density to act to attenuate by a predetermined amount transferred between the first and second optical fibers. Splicer. 44. The connector of claim 43, wherein said first, second, third, fourth arm, base, filter, and top cap are disposed in a housing. 45. A connector according to claim 44, wherein said first, second, third, and fourth arms and said base portion are disposed in a housing. 40. The system of claim 39, wherein the optical element comprises an attenuator, wherein the predetermined wavelength transmitted between the first and second optical fibers is attenuated by a first predetermined amount by the action of the first region of the attenuator, And define a first region by a predetermined light density and a first axis thickness and a second region by a predetermined light density and a second axis thickness to be attenuated by a second predetermined amount by the action of the second region. Connector made. 47. The connector of claim 46, wherein the attenuator is cascaded to define first and second regions. 47. The connector of claim 46, wherein the attenuator is formed of counterbored blocks to define first and second regions. 47. The connector of claim 46, wherein said first, second, third, fourth arm, base, filter, and top cap are disposed in a housing. 50. A connector according to claim 49, wherein said first, second, third and fourth arms and base are disposed in a housing. A connector for positioning a first cylindrical member relative to a second cylindrical member, comprising: a first positioning device for positioning a first cylindrical member having an outer diameter corresponding to a predetermined diameter range, the selected A second positioning device and a base for positioning a second cylindrical member having an outer diameter corresponding to the diameter range, wherein the first positioning device has a side wall, and has a second center from the first closed position. Bias the fingers toward the first closed position with a bias force selected such that the sum of the biasing forces on the fingers is substantially equal to zero when the fingers are in the central position and the set of four fingers capable of moving in position Means for making a side wall of said fingers such that in a closed position a first reference axis passes through a channel having an inlet end and an outlet end Cooperating to define this channel, the first cylindrical member inserted into the inlet end of the channel so that the axis of the first member is spaced from the first reference axis, initially by contacting the axial wall on at least one of the fingers. Each of the fingers is aligned such that the center point on the end face of the first member is displaced to be in line with the reference axis, and the first member is brought into contact by contact between the first member and the contact point on the respective fingers. In response to continuous axial movement of the first member through the channel by deflecting against a bias force to align the center point on the end face of the first reference axis with the first reference axis, the second positioning device having a sidewall And a set of four fingers that are capable of fractionally moving from the first closed position to the second center position and a bias on the fingers when the fingers are in the center position Means for biasing each of the fingers toward the first closed position with a biasing force selected such that the sum of the forces is substantially equal to zero, wherein in the closed position the second reference axis creates a channel with an inlet end and an outlet end. Sidewalls of the fingers cooperate to define this channel to pass through, and a second cylindrical member inserted in the inlet end of the channel such that the axis of the second member is spaced from the second reference axis on at least one of the fingers. Each of the fingers is aligned such that it is initially displaced by contact with the sidewall so that the center point can be moved in line with the reference axis on the end face of the second member, and between the contact point on the respective fingers and the second member By deflecting against the bias force to position the center point on the end face of the second member in line with the second reference axis by contact. In response to the continuous axial movement of the second member through the channel, the second reference axis passing through the second funnel-shaped channel arranged so that the outlet ends of the first and second channels face each other. And two of the fingers in each positioning device are mounted on the foundation such that they are aligned. 53. The device of claim 51, wherein each of the fingers in the positioning device extends in the axial direction and has first and second axis ends, the sidewalls are disposed at the first axis ends, and each of the fingers is formed with the first axis end and the first axis end. Having a thickness reduction portion disposed midway between the two axis ends, where the thickness reduction portion generates a restoring force on each arm to bias each arm toward the closed position when the fingers are deflected by contact with the member. A connector, characterized in that the curved portion is defined within each finger. 52. The connector of claim 51, wherein each of said fingers is made of crystalline material. The apparatus of claim 51, wherein each of the first and second positioning devices further comprises an alignment clamp for engaging the member at a predetermined distance along a reference axis from near all contact points on the sidewalls of the fingers of the positioning devices, And the member engages the member such that the clamp accurately positions the selected second point on the central axis of the member in a straight line with the reference axis. 55. The article of claim 54 wherein the alignment clamp comprises a second positioning device, the second positioning device having sidewalls, and capable of being able to move selectively from the first closed position to the second center position. Means for biasing each of the fingers in the second set toward the first closed position with a biasing force selected such that the sum of the biasing forces on the fingers is substantially equal to zero when the four finger set of two and the fingers are in the central position; The sidewalls of the fingers in the second set such that the reference axis of the clamp in line with the reference axis passing through the positioning device to which the clamp is connected in the closed position passes through a second channel having an inlet end and an outlet end. A cylindrical member cooperated to define this channel and inserted into the inlet end of the second channel so that the axis of the member is spaced from the reference axis of the clamp Each of the fingers in the second set is aligned such that it is initially displaced by contacting a sidewall on one or more of the fingers in the two sets so that the center point on the end face of the portion can be moved in line with the reference axis of the clamp, Responsive to the continuous axial movement of the member through the channel by deflecting against the biasing force to move each of the fingers in the second set to be in line with the reference axis of the clamp to move the second point on the central axis of the member and The biasing force to accurately position the selected second point on the member by the contact between the member and the contact point on the respective finger in the second set to be in line with the reference axis of the clamp. A connector, characterized by deflecting toward. 56. The device of claim 55, wherein each of the fingers in the second positioning is axially extending and has first and second axial ends, the sidewall is disposed at the first axial end, and each of the fingers in the second set is first defined. If the fingers between the first and second axis ends are deflected by contact with the member, define a curved portion in each finger that generates a restoring force on each finger in the second set to bias each finger toward the closed position. A connector, characterized in that. 59. The connector of claim 56, wherein each of the fingers in the second positioning device is made of crystalline material. 56. The connector of claim 55, wherein the first and second positioning devices are disposed in a housing. 55. The connector of claim 54, wherein the first and second positioning devices are disposed in a housing. 52. The connector of claim 51, wherein the first and second positioning devices are disposed in a housing. 53. The apparatus of claim 51, wherein the first and second cylindrical members each comprise an optical fiber having ends, and wherein the first and second optical fibers are defined such that a predetermined gap is defined between the ends of each optical fiber. And the positioning device is positioned by the second positioning device. The optical fiber according to claim 21, wherein the first and second cylindrical members are optical fibers that operate to transmit light, and when the first and second positioning devices are axially separated by a gap, the gap is in a straight line. And an optical element having a predetermined axis size along an aligned reference axis, wherein the connector further comprises an optical element disposed in a gap of the first and second positioning devices. 63. The connector of claim 62, wherein the optical element comprises a filter. 66. The connector of claim 63, wherein the first, second, third and fourth arms, the foundation, the filter and the upper cap are disposed within the housing. 65. A connector according to claim 64, wherein said first, second, third and fourth arms and said base portion are disposed in a housing. 63. The attenuator of claim 62, wherein the optical element has a predetermined axis size and a predetermined light density to act to attenuate a predetermined amount of light of a predetermined wavelength transmitted between the first and second optical fibers. A connector, characterized in that it comprises. 67. The connector of claim 66, wherein said first, second, third and fourth arms, base, filter and top cap are disposed within a housing. 68. The connector of claim 67, wherein said first, second, third, and fourth arms and said base portion are disposed within a housing. 63. The apparatus of claim 62, wherein the optical element comprises an attenuator, wherein the predetermined wavelength delivered by the attenuator between the first and second optical fibers is attenuated by a first predetermined amount by the action of the first region of the attenuator, And define a first region by a predetermined light density and a first axis thickness and a second region by a predetermined light density and a second axis thickness to be attenuated by a second predetermined amount by the action of the second region. Connector made. 70. The connector of claim 69, wherein said attenuator is cascaded to define first and second regions. 70. The connector of claim 69, wherein said attenuator is formed of counterbored blocks to define first and second regions. 70. The connector of claim 69, wherein the first, second, third and fourth arms, the foundation, the filter and the upper cap are disposed in a housing. 73. The connector of claim 72, wherein said first, second, third, and fourth arms and said base portion are disposed within a housing. 55. The apparatus of claim 54, wherein the first and second cylindrical members each comprise an optical fiber having ends, and wherein the first and second optical fibers are defined such that a predetermined gap is defined between the ends of each optical fiber. And the positioning device is positioned by the second positioning device. 55. The apparatus of claim 54, wherein the first and second cylindrical members are optical fibers that operate to transmit light, and when the first and second positioning devices are axially separated by a gap, the gap is in a straight line. And an optical element having a predetermined axis size along an aligned reference axis, wherein the connector further comprises an optical element disposed in a gap of the first and second positioning devices. 76. The connector of claim 75, wherein the optical element comprises a filter. 77. The connector of claim 76, wherein said first, second, third and fourth arms, base, filter and top cap are disposed within a housing. 78. The connector of claim 77, wherein said first, second, third, and fourth arms and said base portion are disposed within a housing. 77. The attenuator of claim 75, wherein the optical element has a predetermined axis size and a predetermined light density to act to attenuate a predetermined amount of light of a predetermined wavelength transmitted between the first and second optical fibers. A connector, characterized in that it comprises. 80. The connector of claim 79, wherein the first, second, third and fourth arms, the foundation, the filter and the upper cap are disposed in a housing. 81. The connector of claim 80, wherein said first, second, third, and fourth arms and said base portion are disposed within a housing. 76. The device of claim 75, wherein the optical element comprises an attenuator, wherein the predetermined wavelength transmitted by the attenuator between the first and second optical fibers is attenuated by a first predetermined amount by the action of the first region of the attenuator, And define a first region by a predetermined light density and a first axis thickness and a second region by a predetermined light density and a second axis thickness to be attenuated by a second predetermined amount by the action of the second region. Connector made. 83. The connector of claim 82, wherein the attenuator is cascaded to define first and second regions. 83. The connector of claim 82, wherein the attenuator is formed of counterbored blocks to define first and second regions. 83. The connector of claim 82, wherein the first, second, third and fourth arms, the foundation, the filter and the upper cap are disposed in a housing. 86. The connector of claim 85, wherein said first, second, third, and fourth arms and said base portion are disposed within a housing. A method of making an optical fiber-optic fiber connector, comprising: (a) forming first and second arms on a surface of a first silicon wafer, and (b) forming first and second arms on a surface of a second silicon wafer. Forming on the surface of the third silicon wafer a base having a first and a second mounting area, and (d) corresponding first and second on each of the first and second wafers. Securing the first and second wafers in an overlapping relationship so that the grooves cooperate to define the first and second fully funneled channels, (e) securing the first wafer to a mounting area on the second wafer And (f) cutting the overlapping first and second wafers along the dividing line, wherein in step (1) each of the first and second arms has at least first and second sidewalls; Into a converging groove therein, the side walls in each of the first and second arms having an outlet end. Arranged on the surface of the first wafer such that the exit end direction of the converging groove is adjacent, and in step (b), each of the first and second arms has at least first and second sidewalls; And the side walls in each of the first and second arms cooperate to define a converging groove having an outlet end therein, the outlet end of the converging groove being arranged on the surface of the first wafer such that the end direction is adjacent. The connector manufacturing method made into it. 88. The method of claim 87, further comprising: (g) cutting the first and second wafers along the slit line such that the first and second arms defined on each of the first and second wafers are separated to define an arm pair. Method for manufacturing a connector comprising a. ※ Note: The disclosure is based on the initial application.