CN201540400U

CN201540400U - Adjusting structure for microscopic imaging light path of fusion splicer

Info

Publication number: CN201540400U
Application number: CN2009202671880U
Authority: CN
Inventors: 黄木旺; 王敏; 梁秀玲; 陈新景
Original assignee: FUTEKE PHOTOELECTRIC Co Ltd FUZHOU
Current assignee: FUTEKE PHOTOELECTRIC Co Ltd FUZHOU
Priority date: 2009-11-19
Filing date: 2009-11-19
Publication date: 2010-08-04
Anticipated expiration: 2019-11-19

Abstract

The utility model solves the defects in design of the existing light paths, adjusting structures, and the like and provides an easily adjusted and assembled adjusting structure for the microscopic imaging light path of a fusion splicer. The adjusting structure comprises a splicer seat, a microlens installed on the splicer seat and a C-MOS (Complementary Metal Oxide Semiconductor) or a CCD (charge coupled device), wherein the C-MOS or the CCD is positioned on the optic axis direction of the microlens. The adjusting structure is characterized in that: firstly, the microlens and the splicer seat are connected by adopting the following mode: so that the microlens only has the focusing and adjusting functions through one-dimensional axial movement along the optic axis direction of the microlens corresponding to the splicer seat; and secondly, an adjusting device used for adjusting the X position, the Y position and the rotational position of an image on a C-MOS or CCD target surface is arranged between the C-MOS and the splicer seat or between the CCD and the splicer seat.

Description

The adjustment structure of the micro-imaging light path of optical fiber splicer

Technical field

The utility model relates to a kind of adjustment structure of micro-imaging light path of optical fiber splicer.

Background technology

Optical fiber splicer all will be to the fiber end face quality judging before welding, and optical fiber advances the welding of discharging then to directly.These processes all are to carry out imaging at X, Y both direction to optical fiber, and software systems are analyzed the above operation of back control to picture then.The general optical fiber heat sealing machine, its optical fiber micro-imaging of low quality, this just causes the fused fiber splice time error bigger, and light is big in the loss of welding point after the welding.Along with the development of communication, its quality requirements to fused fiber splice is more and more higher, and this makes optical fiber splicer require to improve to the micro-imaging of optical fiber.The raising of this requirement, except image quality, the esolving degree of the head that adjusts the telescope to one's eyes requires to improve, also to whole optical path system, focusing, to medium proposition requirements at the higher level.The microlens of high definition, high imaging quality is not difficult to design, and still, light has good camera lens, and the light path of total system is bad, undesirable, the out of true of adjusting mechanism, and last imaging effect is also bad.Particularly optical fiber splicer has requirement to the position of imaging fiber on C-MOS (or CCD), also will regulate.At present, the producer of this high-precision optical fiber heat sealing machine of domestic production is few, mainly by import.And the light path design of domestic this high-precision optical fiber heat sealing machine is all bad, with all adjusting factors, comprise the focusing of camera lens and fiber position, be imaged on the position that C-MOS (or CCD) goes up X, Y direction, and departing from of causing of other all system's positioning errors all concentrate on the relative position of regulating camera lens and support, comprising: about camera lens and support, front and back, up and down, omnibearing multidimensional adjusting such as pitching.Each factor of this adjusting is interrelated, interacts, very difficult adjusting the, difficult operation.Simultaneously, in this design, camera lens is to rotate by an eccentric rod to realize to the focus adjustment of fiber position axially.And in fact, eccentric rod makes camera lens when axially moving when rotating, and also makes camera lens that the swing of a pitching is arranged, and this swing can influence image space and sharpness again.So present this design, though can reach the image quality requirement in theory, very difficult when regulating assembling in practical operation, make high-precision optical fiber splicer to produce in batches, thereby the cost height, competitive power do not had.

The utility model content

The utility model has solved the defective in the design such as existing light path and adjustment structure, and a kind of adjustment structure that is easy to the micro-imaging light path of the optical fiber splicer regulating and assemble is provided.

The technical scheme that the utility model adopted is as follows:

A kind of adjustment structure of micro-imaging light path of optical fiber splicer, it comprises support and the microlens and C-MOS or the CCD that are installed on the support, described C-MOS or CCD are positioned on the optic axis direction of microlens, it is characterized in that: connect in the following manner between 1. described microlens and the support: make microlens only have the optic axis direction one dimension axially movable focal adjustment function of relative support along microlens; 2. be provided with the regulating device that is used for regulating the X, Y position and the position of rotation that are imaged on C-MOS or the CCD target surface between described C-MOS or CCD and the support.

Realize by being threaded between described microlens and the support: make microlens only have the optic axis direction one dimension axially movable focal adjustment function of relative support along microlens.

Perhaps, described support is provided with and is used for driving optic axis direction one dimension axially movable motor and the gear train thereof of the relative support of microlens along microlens.

Described regulating device can comprise the rotation adjusting moving plate that is connected on the support and be connected in rotates X, the Y adjusting moving plate of regulating between moving plate and C-MOS or the CCD; The relative support of described rotation adjusting moving plate energy is the center rotation with the optic axis of microlens, and support is provided with the fastener of the position of rotation that is used for fixing rotation adjusting moving plate; Described rotation is regulated moving plate and is provided with and is used for regulating and fixedly X, Y regulate moving plate and regulate the X of moving plate, the two-dimentional adjusting gear of Y position with respect to rotation.Concrete, described rotation is regulated moving plate and is placed in the rotating hole of support, and described fastener is regulated the lock-screw that moving plate is rotated further and constituted to prevent to rotate by being used for locking rotating hole; Described X, Y regulate moving plate and are placed on the pipe box inner chamber that moving plate is regulated in rotation, described two-dimentional adjusting gear is made of to spring leaf to set screw, Y to spring leaf, Y to set screw, X the directions X both sides of being located at X, Y adjusting moving plate respectively, the X of Y direction both sides, wherein X is located at rotation to set screw and Y to set screw and regulates in the radial screw bore of pipe box wall of moving plate, and X is located to spring leaf to spring leaf and Y that X, Y regulate moving plate and rotation is regulated between the pipe box inwall of moving plate.

Perhaps, described regulating device can comprise that also the X, the Y that are connected between support and C-MOSS or the CCD and rotation regulate moving plate, and described support is provided with and is used for regulating and fixedly X, Y and rotation are regulated moving plate with respect to X, the Y of support and the two dimension and the rotation compound adjustment device of position of rotation.Concrete, the pipe box inner chamber that moving plate is located at support is regulated in described X, Y and rotation, the directions X both sides of moving plate are regulated in X, Y and rotation, a pair of X of Y direction both sides constitutes to spring leaf to set screw, Y to spring leaf, a pair of Y to set screw, X by being located at respectively for described two dimension and rotation compound adjustment device, wherein in set screw was located at the radial screw bore of pipe box wall of support, X was located at X, Y to spring leaf and Y to spring leaf and regulates between the pipe box inwall of moving plate and support X to set screw and Y.

The control method of the micro-imaging light path of above-mentioned optical fiber splicer is with the complicated adjusting of multidimensional between original single microlens and support, is separated to many places and carries out the one-dimensional minute adjustment.Promptly, with the focusing of optical fiber by microlens imaging on C-MOSS or CCD, and be imaged on X on C-MOSS or the CCD target surface, the adjusting of Y position and rotation is decomposed into from the adjusting of multidimensional relative position between single microlens and support: 1. only keep the axial focal adjustment of optic axis direction one dimension along microlens between microlens and the support, the adjusting that 2. is imaged on X, Y position and position of rotation on C-MOSS or the CCD target surface realizes with X, Y direction relative position and the relative rotation of microlens by regulating C-MOS or CCD.

Change employing precision-fit screw thread manual adjustments or precision electric motor motorized adjustment along the axial focal adjustment of the optic axis direction one dimension of microlens into by excentric shaft adjusting commonly used between microlens and the support.

The utility model provides following two kinds of concrete design proposals for regulating C-MOS or CCD with X, Y direction relative position and the relative rotation of microlens: 1. the specific design scheme one: regulate C-MOS or CCD and separate in two separate mechanisms with X, Y direction relative position and relative rotation of microlens, the X, Y direction relative position that regulates C-MOS or CCD and microlens and the relative rotation of adjusting C-MOS or CCD and microlens not simultaneously, non-interference.2. the specific design scheme two: X, Y direction relative position and the relative Rotation Design of regulating C-MOS or CCD and microlens are in same regulating device. and the relative rotation of regulating X, Y direction relative position and adjusting C-MOS or the CCD and the microlens of C-MOS or CCD and microlens is carried out simultaneously.

Compared to prior art, the utlity model has following advantage: the utility model has taken into full account in optics, the light path design light, mechanical, electrical comprehensive, design the light, mechanical, electrical system that regulates, install of being easy to. make that optical fiber splicer high-accuracy, low insertion loss is convenient, more quick when optical microphotograph is regulated focusing, centering in process of production, also make the batch process of optical fiber splicer of high-accuracy, low insertion loss be more prone to.

Description of drawings

Fig. 1 is the light path of adjustment structure of micro-imaging light path of the optical fiber splicer that provides of the utility model and the axial section synoptic diagram of structure.

Fig. 2 is the accurate thread regulating device synoptic diagram between microlens and support, and Fig. 2 is the I part enlarged diagram of Fig. 1.

Fig. 3 is the precision electric motor motorized adjustment device synoptic diagram between microlens and support, and Fig. 3 is the B-B cut-open view of Fig. 1.

Fig. 4 is when regulating C-MOS or CCD and separating in two separate mechanisms with X, Y direction relative position and the relative rotation of microlens, rotates adjusting part synoptic diagram, and Fig. 4 is the A-A cut-open view of Fig. 1.

Fig. 5 is the E-E cut-open view of Fig. 4.

Fig. 6 is when regulating C-MOS or CCD and separating in two separate mechanisms with X, Y direction relative position and the relative rotation of microlens, the adjusting part synoptic diagram of adjusting X, Y direction relative position, and Fig. 6 is the C-C cut-open view of Fig. 7.

Fig. 7 is the right view of Fig. 6.

Fig. 8 is that X, Y direction relative position and the relatively rotation place of regulating C-MOS or CCD and microlens design in same regulating device, and X, Y and rotation are the adjusting part synoptic diagram of regulating simultaneously, and Fig. 8 is the D-D cut-open view of Fig. 9.

Fig. 9 is the right view of Fig. 8.

Number in the figure explanation: 1-fiber bench, 2-support, 3-microlens, moving plate is regulated in the 4-rotation, and 5-X, Y regulate moving plate, 6-CMOS or CCD, 7-lock-screw, 8-X are to set screw, and 8 '-Y is to set screw, 9-X is to spring leaf, and 9 '-Y is to spring leaf, the 10-gear train, the 11-motor, moving plate, 13-rotating hole are regulated in 12-X, Y and rotation, the 14-LED lamp, 15-LED light beam, 16-catoptron.

Embodiment

Below in conjunction with Figure of description and specific embodiment the utility model content is elaborated:

The adjustment structure embodiment synoptic diagram of the micro-imaging light path of a kind of optical fiber splicer that Fig. 1 provides for the utility model, be illustrated as the index path of whole ray machine electricity structure, in order to embody between microlens and the support two kinds of different adjustment modes preferably along the axial focal adjustment of the optic axis direction one dimension of microlens, Fig. 1 will adopt precision-fit screw thread manual adjustments and two kinds of regulative modes of precision electric motor motorized adjustment to concentrate on performance (the first from left right side) among the figure, during concrete enforcement, can adopt identical or different regulative mode in the same mechanism.

As shown in fig. 1, comprise support 2 and the microlens 3 and C-MOS or the CCD6 that are installed on the support 2, described C-MOS or CCD6 are positioned on the optic axis direction of microlens 3, it is characterized in that: connect in the following manner between 1. described microlens 3 and the support 2: make microlens only have the optic axis direction one dimension axially movable focal adjustment function of relative support 2 along microlens 3; 2. be provided with the regulating device that is used for regulating the X, Y position and the position of rotation that are imaged on C-MOS or the CCD6 target surface between described C-MOS or CCD6 and the support 2.

The control method of the micro-imaging light path of above-mentioned optical fiber splicer is characterized in that: multidimensional is complicated between microlens that will be original single and support regulates, and is separated to many places and carries out the one-dimensional minute adjustment.Promptly, with the focusing of optical fiber by microlens 3 imaging on C-MOS or CCD, and be imaged on X on C-MOS or the CCD target surface, the adjusting of Y position and rotation is decomposed into from the adjusting of

single microlens

3 and 2 multidimensional relative positions of support: 1. only keep the axial focal adjustment of optic axis direction one dimension along microlens 3 between microlens 3 and the support 2, the adjusting that 2. is imaged on X, Y position and position of rotation on C-MOS or the CCD target surface realizes with X, Y direction relative position and the relative rotation of microlens 3 by regulating C-MOS or CCD.

Described C-MOS or CCD6 are imager chip and circuit board thereof.

As shown in Figure 2, realize by being threaded between described microlens 3 and the support 2: make microlens only have the optic axis direction one dimension axially movable focal adjustment function of relative support 2 along microlens 3.Change employing precision-fit screw thread manual adjustments along the axial focal adjustment of the optic axis direction one dimension of microlens 3 into by excentric shaft adjusting commonly used between microlens 3 and the support 2.Rotate microlens 3 and be the scalable microlens in the optical axis direction of microlens and moving to axial of support, thus adjusting microlens and thing (optical fiber), as the distance between (C-MOS).

Perhaps, as shown in Figure 3, described support 2 is provided with and is used for driving optic axis direction one dimension axially movable motor 11 and the gear train 10 thereof of microlens 3 relative supports 2 along microlens 3.Change employing precision electric motor motorized adjustment along the axial focal adjustment of the optic axis direction one dimension of microlens 3 into by excentric shaft adjusting commonly used between microlens 3 and the support 2.

The utility model also provides following two kinds of concrete design proposals for regulating C-MOS or CCD with X, Y direction relative position and the relative rotation of microlens 3:

1. the specific design scheme one: regulate C-MOS or CCD6 and separate in two separate mechanisms with X, Y direction relative position and the relative rotation of microlens 3, the X, Y direction relative position that regulates C-MOS or CCD6 and microlens 3 and the relative rotation of adjusting C-MOS or CCD6 and microlens 3 not simultaneously, non-interference.

As Fig. 4-shown in Figure 7, described regulating device comprises that the rotation that is connected on the support 2 is regulated moving plate 4 and is connected in rotation and regulates X, Y adjusting moving plate 5 between moving plate 4 and C-MOS or the CCD6; The relative support 2 of described rotation adjusting moving plate 4 energy is the center rotation with the optic axis of microlens 3, and support 2 is provided with the fastener 7 of the position of rotation that is used for fixing rotation adjusting moving plate 4; Described rotation is regulated moving plate 4 and is provided with and is used for regulating and fixedly X, Y regulate moving plate 5 and regulate the X of moving plate 4, the two-dimentional adjusting gear of Y position with respect to rotation.It also is simultaneously the still that X, Y regulate moving plate that moving plate 4 is regulated in described rotation.

Described rotation is regulated moving plate 4 and is placed in the rotating hole 13 of support 2, and described fastener 7 is regulated the lock-screw that moving plate 4 is rotated further and constituted to prevent to rotate by being used for locking rotating hole 13; Described X, Y regulate moving plate 5 and are placed on the pipe box inner chamber that moving plate 4 is regulated in rotation, described two-dimentional adjusting gear is made of to spring leaf 9 ' to set screw 8 ', Y to spring leaf 9, Y to set screw 8, X the X of the directions X both sides of being located at X, Y adjusting moving plate 5 respectively, Y direction both sides, wherein X is located at rotation to set screw 8 and Y to set screw 8 ' and regulates in the radial screw bore of pipe box wall of moving plate 4, and X is located to spring leaf 9 ' to spring leaf 9 and Y that X, Y regulate moving plate 5 and rotation is regulated between the pipe box inwall of moving plate 4.

During adjusting, rotate microlens 3 earlier, instrumentality, image distance make optical fiber produce clearly as (seeing imaging results by display screen) at C-MOS or CCD6.Then the rotation rotation is regulated moving plate 4 and is regulated X to set screw 8, make the imaging level of optical fiber on C-MOS or CCD6, the picture that is optical fiber is parallel with bottom on the screen on the display screen, directions X position on the display screen of imaging fiber meets the requirements simultaneously, and is by fastener 7 that the rotating hole 13 of support 2 is locked with rotation adjusting moving plate 4 afterwards.Regulate Y at last to set screw 8 ', promptly the scalable imaging fiber makes the imaging fiber position meet the requirements in the Y of display screen direction position.If necessary, also regulate microlens 3 possibly again and reach the most clear at the optical axis direction of microlens 3 and the picture that makes on the display screen that moves to axial of support 2.After regulating, in order to prevent that the vibration effect in the processes such as use generally will be fixed above all movable adjusting parts with glue, cement in transportation.

2. the specific design scheme two: X, Y direction relative position and the relative Rotation Design of regulating C-MOS or CCD6 and microlens 3 are in same regulating device. and the relative rotation of regulating X, Y direction relative position and adjusting C-MOS or the CCD6 and the microlens 3 of C-MOS or CCD6 and microlens 3 is carried out simultaneously.

As Fig. 8-shown in Figure 9, described regulating device comprises that the X, the Y that are connected between support 2 and C-MOS or the CCD6 and rotation regulate moving plate 12, and described support 2 is provided with and is used for regulating and fixedly X, Y and rotation are regulated moving plate 12 with respect to X, the Y of support 2 and the two dimension and the rotation compound adjustment device of position of rotation.

Described X, Y and rotation are regulated moving plate 12 and are located at the pipe box inner chamber of support 2 (among Fig. 8-Fig. 9, it is fixing dead by fastener 7 that moving plate 4 is regulated in rotation among Fig. 4-Fig. 7, the pipe box of rotation adjusting moving plate 4 promptly is equivalent to and is used for being nested with X on the support 2, a fixed pipe box of moving plate 12 is regulated in Y and rotation, during concrete enforcement, also can directly on support 2, be provided with one and be used for being nested with X, the pipe box of moving plate 12 is regulated in Y and rotation), described two dimension and rotation compound adjustment device are by being located at X respectively, the directions X both sides of moving plate 12 are regulated in Y and rotation, the a pair of X of Y direction both sides is to set screw 8, X is to spring leaf 9, a pair of Y is to set screw 8 ', Y constitutes to spring leaf 9 ', wherein in set screw 8 ' was located at the radial screw bore of pipe box wall of support 2, X was located at X to spring leaf 9 and Y to spring leaf 9 ' to X to set screw 8 and Y, Y regulates between the pipe box inwall of moving plate 5 and support 2.

During adjusting, rotate microlens 3 earlier, instrumentality, image distance make optical fiber produce clearly as (seeing imaging results by display screen) at C-MOS or CCD6.Then regulate a pair of X respectively to set screw 8 and a pair of Y position to set screw 8 ', making X, Y and rotation regulate moving plate 12 carries out synchronously with respect to the adjusting of the adjusting of the position of rotation of support 2 and X, Y direction position, if necessary, also regulate microlens 3 possibly again and reach the most clear at the optical axis direction of microlens 3 and the picture that makes on the display screen that moves to axial of support 2.After regulating, in order to prevent that the vibration effect in the processes such as use generally will be fixed above all movable adjusting parts with glue, cement in transportation.

Claims

1. the adjustment structure of the micro-imaging light path of an optical fiber splicer, it comprises support (2) and is installed in microlens (3) and C-MOS or CCD (6) on the support (2), described C-MOS or CCD (6) are positioned on the optic axis direction of microlens (3), it is characterized in that: connect in the following manner between 1. described microlens (3) and the support (2): make microlens only have the optic axis direction one dimension axially movable focal adjustment function of relative support (2) along microlens (3); 2. be provided with between described C-MOS or CCD (6) and the support (2) and be used for regulating the regulating device that is imaged on X, Y position and position of rotation on C-MOS or CCD (6) target surface.

2. the adjustment structure of the micro-imaging light path of optical fiber splicer according to claim 1 is characterized in that: realize by being threaded between described microlens (3) and the support (2): make microlens only have the optic axis direction one dimension axially movable focal adjustment function of relative support (2) along microlens (3).

3. the adjustment structure of the micro-imaging light path of optical fiber splicer according to claim 1 is characterized in that: described support (2) be provided be used for driving microlens (3) relatively support (2) along the axially movable motor of optic axis direction one dimension (11) and the gear train (10) thereof of microlens (3).

4. the adjustment structure of the micro-imaging light path of optical fiber splicer according to claim 1 is characterized in that: described regulating device comprises that the rotation that is connected on the support (2) is regulated moving plate (4) and is connected in rotation and regulates X, Y adjusting moving plate (5) between moving plate (4) and C-MOS or the CCD (6); The relative support (2) of described rotation adjusting moving plate (4) energy is the center rotation with the optic axis of microlens (3), and support (2) is provided with the fastener (7) of the position of rotation that is used for fixing rotation adjusting moving plate (4); Described rotation is regulated moving plate (4) and is provided with and is used for regulating and fixedly X, Y regulate moving plate (5) and regulate the X of moving plate (4), the two-dimentional adjusting gear of Y position with respect to rotation.

5. the adjustment structure of the micro-imaging light path of optical fiber splicer according to claim 4, it is characterized in that: described rotation is regulated moving plate (4) and is placed in the rotating hole (13) of support (2), and described fastener (7) is regulated the lock-screw formation that moving plate (4) is rotated further by being used for locking rotating hole (13) to prevent rotation; Described X, Y regulates moving plate (5) and is placed on the pipe box inner chamber that moving plate (4) is regulated in rotation, described two-dimentional adjusting gear is by being located at X respectively, Y regulates the directions X both sides of moving plate (5), the X of Y direction both sides is to set screw (8), X is to spring leaf (9), Y is to set screw (8 '), Y constitutes to spring leaf (9 '), wherein X is located at rotation to set screw (8) and Y to set screw (8 ') and regulates in the radial screw bore of pipe box wall of moving plate (4), and X is located at the pipe box inwall and the X of rotation adjusting moving plate (4) to spring leaf (9 ') to spring leaf (9) and Y, Y regulates between the moving plate (5).

6. the adjustment structure of the micro-imaging light path of optical fiber splicer according to claim 1, it is characterized in that: described regulating device comprises that the X, the Y that are connected between support (2) and C-MOS or the CCD (6) and rotation regulate moving plate (12), and described support (2) is provided with and is used for regulating and fixedly X, Y and rotation are regulated moving plate (12) with respect to X, the Y of support (2) and the two dimension and the rotation compound adjustment device of position of rotation.

7. the adjustment structure of the micro-imaging light path of optical fiber splicer according to claim 6, it is characterized in that: described X, the pipe box inner chamber that moving plate (12) is located at support (2) is regulated in Y and rotation, described two dimension and rotation compound adjustment device are by being located at X respectively, the directions X both sides of moving plate (12) are regulated in Y and rotation, the a pair of X of Y direction both sides is to set screw (8), X is to spring leaf (9), a pair of Y is to set screw (8 '), Y constitutes to spring leaf (9 '), wherein in set screw (8 ') was located at the radial screw bore of pipe box wall of support (2), X was located at the pipe box inwall and the X of support (2) to X to spring leaf (9 ') to spring leaf (9) and Y to set screw (8) and Y, Y regulates between the moving plate (5).