CN207351659U - Eyeglass detects and calibration tool - Google Patents
Eyeglass detects and calibration tool Download PDFInfo
- Publication number
- CN207351659U CN207351659U CN201721081468.3U CN201721081468U CN207351659U CN 207351659 U CN207351659 U CN 207351659U CN 201721081468 U CN201721081468 U CN 201721081468U CN 207351659 U CN207351659 U CN 207351659U
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- eyeglass
- adjustment frame
- rangefinder
- calibration tool
- sliding block
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Abstract
Eyeglass detection field is the utility model is related to, more particularly, to a kind of detection of eyeglass and calibration tool.It is not high and detect the problem of data can not directly be read to alleviate accuracy of detection existing in the prior art.Including eyeglass adjustment frame, for installing eyeglass, the eyeglass can be driven to be moved in the horizontal plane along the axis direction perpendicular to the eyeglass, and the axis direction that can surround the eyeglass rotates the eyeglass.Locator is used for the horizontality for judging eyeglass.Rangefinder can move up and down and can be along the axis direction horizontal movement for the eyeglass being installed in the eyeglass adjustment frame, for reading the optical data of eyeglass.The positioning of eyeglass is realized by eyeglass adjustment frame and locator, the measurement of optical data is realized by rangefinder, and rangefinder can realize directly reading for optical data, and detection process more automates, the not high technical problem of the precision artificially measured is avoided.
Description
Technical field
Eyeglass detection field is the utility model is related to, more particularly, to a kind of detection of eyeglass and calibration tool.
Background technology
Galvanometer eyeglass be scanning galvanometer in the scan control application process to laser, pass through the pendulum of X and Y reflecting optics
It is dynamic, laser is realized in working face and is accurately positioned at a high speed.Since laser directly acts on galvanometer lens surface, so galvanometer
Adhesive reinforcement just become vibration mirror scanning application important foundation, and as the appraisal standards of galvanometer quality and optical property it
One, final Laser Processing effect will be directly influenced.
Common eyeglass detection method is reflection feux rouges swing method.But this mode can not accurately detect eyeglass to rotation
Turn the data such as the depth of parallelism of central shaft, symmetry, data cannot directly be read, and accuracy of detection is not high.
Thus, eyeglass of the prior art detection is not high there are accuracy of detection and detects data and can not directly read etc. and asks
Topic.
Utility model content
It is existing in the prior art to alleviate the purpose of this utility model is to provide a kind of detection of eyeglass and calibration tool
Accuracy of detection is not high and detects the problem of data can not directly be read.
In order to solve the above technical problems, technical solution provided by the utility model is:
A kind of eyeglass detection and calibration tool, including:
Eyeglass adjustment frame, for installing eyeglass, can drive the eyeglass in the horizontal plane along perpendicular to the eyeglass
Axis direction moves, and the axis direction that can surround the eyeglass rotates the eyeglass;
Locator, for judging the horizontality of eyeglass;
Rangefinder, can move up and down and can be along the axis direction water for the eyeglass being installed in the eyeglass adjustment frame
Flat movement, for reading the optical data of eyeglass.
Further,
The eyeglass adjustment frame includes:
Adjustment frame housing, has through hole;
Locating shaft, through the through hole, is detachably connected and installation end with the adjustment frame housing by latch assembly
It is provided with clamping opening.
Further,
The latch assembly includes the first positioner and the second positioner,
First positioner includes clip and locking member, and two free ends of the clip are provided with perforate, institute
Locking member is stated through two perforates to adjust the tightness of clip;
Second positioner offsets through the adjustment frame housing and end with the locating shaft.
Further,
The eyeglass adjustment frame further includes the first sliding equipment, and first sliding equipment includes the first sliding block and first and slides
Rail, first sliding block are connected with the adjustment frame housing, and first sliding block is used to drive the adjustment frame along described first
Slide moves.
Further,
The locator includes retainer body and locating rod;
The locating rod is connected with the retainer body by telescopic component, the locating rod and the telescopic component
Telescopic direction is vertical and axial line is perpendicular to the plane where the eyeglass.
Further,
The rangefinder further includes height adjustment mechanism;
The height adjustment mechanism include fixed frame, the activity framework for being set in the fixed frame, top with it is described
The telescoping rod of the fixed frame is stretched into the connection of activity framework and bottom, wherein, the rangefinder and the activity framework
Connection.
Further,
The rangefinder further includes the second sliding equipment, and second sliding equipment includes the second sliding block and the second slide,
Second sliding block is connected by connecting plate with the fixed frame;Second slide extends perpendicularly to described first
The extending direction of slide.
Further,
The rangefinder further includes driving device, and the driving device acts on the second cunning of second sliding equipment
Block, for driving second sliding block to be slided along second slide.
Further,
The frock is provided with locating shaft and substitutes area, and the locating shaft substitutes the positioning that area is preset with multiple and different models
Axis.
Further,
Bottom plate is further included, the eyeglass adjustment frame, the locator, the rangefinder, the locating shaft substitute area and set
In the top of the bottom plate.
A kind of eyeglass detection and calibration method, including:
Selection and the matched locating shaft of eyeglass to be detected, eyeglass adjustment frame, rotated locating shaft are installed on by the locating shaft
Until the free end of the locating rod of the reflecting surface contact locator of eyeglass level and eyeglass, is just positioned with completing level;
The direction of eyeglass adjustment frame along first slide is driven to move until the eyeglass adjustment frame is located at rangefinder
Workspace;
The height of rangefinder is adjusted to meet ranging requirement, rangefinder is slided along the second slide direction, to read eyeglass axis
Every detection data in line direction;
Rotated locating shaft until eyeglass be in vertical state, read vertical state to the every of eyeglass detect data.
With reference to above technical scheme, the beneficial effect that the utility model can reach is:
During specifically used, eyeglass to be detected is installed on eyeglass adjustment frame, since eyeglass adjustment frame can surround
The axis rotation of eyeglass, thus rotary fine adjustment eyeglass can be passed through.Since locator can determine that the horizontality of eyeglass, thus
The cooperation of adjustment frame and locator enables to eyeglass holding horizontal.After eyeglass level, mobile eyeglass is so that eyeglass is located at survey
The workspace of distance meter, namely positioned at rangefinder can test zone.Since rangefinder can move up and down, surveyed so as to adjust
Spacing between distance meter and eyeglass is to adapt to different measurement demands.After the completion of the height adjustment of rangefinder, rangefinder is driven
Along the axis direction horizontal movement for the eyeglass being installed in the eyeglass adjustment frame, to read each optics of eyeglass axis direction
Data.
It was found from the above-mentioned course of work, in technical solution provided by the utility model, by eyeglass adjustment frame and determine
Position device realizes the positioning of eyeglass, the measurement of optical data is realized by rangefinder, and rangefinder can realize optics number
According to directly read, detection process more automates, and avoids the not high technical problem of the precision artificially measured.
Brief description of the drawings
, below will be right in order to illustrate more clearly of the utility model embodiment or technical solution of the prior art
Embodiment or attached drawing needed to be used in the description of the prior art are briefly described, it should be apparent that, describe below
In attached drawing be the utility model some embodiments, for those of ordinary skill in the art, do not paying creativeness
On the premise of work, other attached drawings can also be obtained according to these attached drawings.
Fig. 1 is the structure diagram of the eyeglass detection that the utility model embodiment provides and calibration tool;
Fig. 2 is the structure diagram of the eyeglass detection that the utility model embodiment provides and calibration tool;
Fig. 3 is the top view of the eyeglass detection that the utility model embodiment provides and calibration tool;
Fig. 4 is the enlarged drawing of the eyeglass detection that the utility model embodiment provides and the eyeglass adjustment frame in calibration tool.
Icon:100- eyeglass adjustment frames;200- locators;300- rangefinders;400- locating shafts substitute area;110-
Adjustment frame housing;120- locating shafts;130- latch assemblies;The first positioners of 131-;The second positioners of 132-;
The first sliding equipments of 140-;The first sliding blocks of 141-;The first slides of 142-;210- retainer bodies;220- locating rods;310-
Height adjustment mechanism;311- fixed frames;312- activity frameworks;The second sliding equipments of 320-.
Embodiment
The technical solution of the utility model is clearly and completely described below in conjunction with attached drawing, it is clear that described
Embodiment is the utility model part of the embodiment, instead of all the embodiments.Based on the embodiment in the utility model, sheet
Field those of ordinary skill all other embodiments obtained without making creative work, belong to this practicality
Novel protected scope.
, it is necessary to explanation in the description of the utility model, term " " center ", " on ", " under ", it is "left", "right", " perpendicular
Directly ", the orientation of the instruction such as " level ", " interior ", " outer " or position relationship are based on orientation shown in the drawings or position relationship, are only
Described for the ease of description the utility model and simplifying, rather than instruction or imply signified device or element must have it is specific
Orientation, with specific azimuth configuration and operation, therefore it is not intended that limitation to the utility model.In addition, term " the
One ", " second ", " the 3rd " are only used for description purpose, and it is not intended that instruction or hint relative importance.
, it is necessary to which explanation, unless otherwise clearly defined and limited, term " are pacified in the description of the utility model
Dress ", " connected ", " connection " should be interpreted broadly, for example, it may be fixedly connected or be detachably connected, or integratedly
Connection;Can mechanically connect or be electrically connected;It can be directly connected, can also be indirectly connected by intermediary,
It can be the connection inside two elements.For the ordinary skill in the art, above-mentioned art can be understood with concrete condition
Concrete meaning of the language in the utility model.
Embodiment 1 and embodiment 2 are described in detail below in conjunction with the accompanying drawings:
Fig. 1 is the structure diagram of the eyeglass detection that the utility model embodiment provides and calibration tool;Fig. 2 is this practicality
The eyeglass detection and the structure diagram of calibration tool that new embodiment provides;Fig. 3 is the mirror that the utility model embodiment provides
Piece detects and the top view of calibration tool;Fig. 4 is the mirror in the eyeglass detection and calibration tool that the utility model embodiment provides
The enlarged drawing of piece adjustment frame.
Embodiment 1
A kind of eyeglass detection and calibration tool are present embodiments provided, including:
Eyeglass adjustment frame 100, for installing eyeglass, can drive eyeglass in the horizontal plane along perpendicular to the axis side of eyeglass
To movement, and the axis direction rotation eyeglass of eyeglass can be surrounded;
Locator 200, for judging the horizontality of eyeglass;
Rangefinder 300, can move up and down and can be along the axis direction for the eyeglass being installed in eyeglass adjustment frame 100
Horizontal movement, for reading the optical data of eyeglass.
During specifically used, eyeglass to be detected is installed on eyeglass adjustment frame 100, due to 100 energy of eyeglass adjustment frame
Axis enough around eyeglass rotates, thus can pass through rotary fine adjustment eyeglass.Since locator 200 can determine that the level of eyeglass
State, thus the cooperation of adjustment frame and locator 200 enables to eyeglass holding horizontal.After eyeglass level, mobile eyeglass with
Eyeglass is located at the workspace of rangefinder 300, namely positioned at rangefinder 300 can test zone.Due to rangefinder 300 can on
Lower movement, so as to adjust the spacing between rangefinder 300 and eyeglass to adapt to different measurement demands.In rangefinder 300
Height adjustment after the completion of, the horizontal fortune of axis direction of driving rangefinder 300 along the eyeglass being installed in eyeglass adjustment frame 100
It is dynamic, to read each optical data of eyeglass axis direction.
It was found from the above-mentioned course of work, in technical solution provided in this embodiment, by eyeglass adjustment frame 100 and determine
Position device 200 realizes the positioning of eyeglass, the measurement of optical data is realized by rangefinder 300, and rangefinder 300 can be real
Existing optical data is directly read, and detection process more automates, and avoids the not high technical problem of the precision artificially measured.
In the alternative of the present embodiment, more preferably,
Eyeglass adjustment frame 100 includes adjustment frame housing 110 and locating shaft 120.Adjustment frame housing 110 is provided with through hole.
Locating shaft 120 passes through through hole, is detachably connected with adjustment frame housing 110 by latch assembly 130 and installation end is provided with folder
Mouthful.Further, locating shaft 120 includes bar portion and head, and bar portion is fixedly connected with head, and the free end of bar portion is provided with
Clamping opening, clamping opening are used for clipped lens.
In the alternative of the present embodiment, more preferably,
Latch assembly 130 includes the first positioner 131 and the second positioner 132.
First positioner 131 includes clip and locking member, and two free ends of clip are provided with perforate, and locking member is worn
Two perforates are crossed to adjust the tightness of clip.Clip is located between adjustment frame housing 110 and the head of locating shaft 120, also
It is capable of head and the adjustment frame housing 110 of positioned at intervals axis 120.Further, locking member can be bolt.
Second positioner 132 offsets through adjustment frame housing 110 and end with locating shaft 120.Further,
Two positioners 132 are arranged to bolt, and the bar portion of bolt passes through the bar portion after adjustment frame housing 110 with locating shaft 120 to offset.
In the alternative of the present embodiment, more preferably,
Eyeglass adjustment frame 100 further includes the first sliding equipment 140, and the first sliding equipment 140 includes the first sliding block 141 and the
One slide 142, the first sliding block 141 are connected with adjustment frame housing 110, and the first sliding block 141 is used to drive adjustment frame along the first slide
142 movements.Further, the type of drive of the first sliding block 141 is manual actuation, holds the first sliding block 141 or with first
Position of the adjustment frame housing 110 that sliding block 141 connects with the first sliding block 141 of fine setting relative to the first slide 142.Adjust manually
Mode flexibility higher, and cost is lower.Further, the type of drive of the first sliding block 141 is automatically controlled driving, such as the
One sliding block 141 is connected with spindle motor mechanism, and motor driving guide screw movement, leading screw promotes the first sliding block 141 along the first slide 142
Slide.The mode precision higher of automatically controlled driving, adaptability are stronger.
In the alternative of the present embodiment, more preferably,
Locator 200 includes retainer body 210 and locating rod 220;Locating rod 220 passes through with retainer body 210
Telescopic component connects, and locating rod 220 is vertical with the telescopic direction of telescopic component and axial line is perpendicular to flat where eyeglass
Face.Telescopic component is for example including the first slide plate and the second slide plate.One end of first slide plate is installed on retainer body 210, separately
One end is connected with the second slide plate, and one end away from the first slide plate of the second slide plate is connected with locating rod 220, and locating rod 220 is vertical
Plane where the second slide plate.Pulley is provided with first slide plate, slide is provided with the second slide plate, alternatively, the first slide plate
On be provided with slide, be provided with pulley on the second slide plate.Certainly, above-mentioned pulley structure can also pass through the other structures such as axle sleeve
Substitute.
In the alternative of the present embodiment, more preferably,
Rangefinder 300 further includes height adjustment mechanism 310;Height adjustment mechanism 310 includes fixed frame 311, is set in
Activity framework 312, top and the activity framework 312 of fixed frame 311 connect and the telescopic rod of fixed frame 311 is stretched into bottom
Part, wherein, rangefinder 300 is connected with activity framework 312.
In the alternative of the present embodiment, more preferably,
Rangefinder 300 further includes the second sliding equipment 320, and the second sliding equipment 320 includes the second sliding block and the second slide,
Second sliding block is connected by connecting plate with fixed frame 311;The extension for extending perpendicularly to the first slide 142 of second slide
Direction.Further, the type of drive of the second sliding block is manual actuation, hand-held second sliding block or is connected with the second sliding block
Position of the fixed frame 311 with the second sliding block of fine setting relative to the second slide.The mode flexibility higher adjusted manually, and into
This is lower.Further, the type of drive of the second sliding block is automatically controlled driving, such as the second sliding block and spindle motor mechanism phase
Even, motor driving guide screw movement, leading screw promote the second sliding block to be slided along the second slide.The mode precision higher of automatically controlled driving, is fitted
Answering property is stronger.
In the alternative of the present embodiment, more preferably,
Rangefinder 300 further includes driving device, and driving device acts on the second sliding block of the second sliding equipment 320, is used for
The second sliding block is driven to be slided along the second slide.Driving device for example can be spindle motor mechanism, or hydraulic mechanism.
In the alternative of the present embodiment, more preferably,
Frock is provided with locating shaft 120 and substitutes area 400, and locating shaft 120 substitutes area 400 and is preset with determining for multiple and different models
Position axis 120.Since the afterbody of different eyeglasses needs various sizes of clamping opening to clamp eyeglass, thus needed for different eyeglasses
It is equipped with different locating shafts 120.Locating shaft 120 is set to substitute area 400, being capable of personnel's unrestricted choice easy to use.It is specific and
Speech, locating shaft 120, which substitutes area 400, includes mounting cylinder, and multiple mounting grooves are provided with mounting cylinder, locating shaft is accommodated in mounting groove
120。
Embodiment 2
A kind of eyeglass detection and calibration method are present embodiments provided, including:
S1:Selection and the matched locating shaft 120 of eyeglass to be detected, eyeglass adjustment frame 100 is installed on by locating shaft 120, is revolved
Turn locating shaft 120 until the reflecting surface of eyeglass level and eyeglass contacts the free end of the locating rod 220 of locator 200, with complete
Just positioned into level;
S2:Driving eyeglass adjustment frame 100 is moved along the direction of the first slide 142 until eyeglass adjustment frame 100 is located at ranging
The workspace of instrument 300;
S3:The height of rangefinder 300 is adjusted to meet ranging requirement, rangefinder 300 is slided along the second slide direction, to read
Every detection data of appearance piece axis direction;
S4:Rotated locating shaft 120 until eyeglass be in vertical state, reading vertical state to eyeglass every testing number
According to.
It was found from the above-mentioned course of work, in technical solution provided in this embodiment, by eyeglass adjustment frame 100 and determine
Position device 200 realizes the positioning of eyeglass, the measurement of optical data is realized by rangefinder 300, and rangefinder 300 can be real
Existing optical data is directly read, and detection process more automates, and avoids the not high technical problem of the precision artificially measured.
Further, in above-mentioned steps S1, more specifically, the first positioner 131 and the second positioner are rotated
132 with locking positioning axis 120 in eyeglass adjustment frame 100.
Further, in above-mentioned steps S2, more specifically, manual actuation eyeglass adjustment frame 100 is along the first slide 142
Direction movement until eyeglass adjustment frame 100 is located at the workspace of rangefinder 300;Or automatically controlled 100 edge of driving eyeglass adjustment frame
The direction movement of first slide 142 is until eyeglass adjustment frame 100 is located at the workspace of rangefinder 300;
Finally it should be noted that:Various embodiments above is only to illustrate the technical solution of the utility model, rather than it is limited
System;Although the utility model is described in detail with reference to foregoing embodiments, those of ordinary skill in the art should
Understand:It can still modify the technical solution described in foregoing embodiments, either to which part or whole
Technical characteristic carries out equivalent substitution;And these modifications or replacement, the essence of appropriate technical solution is departed from this practicality newly
The scope of each embodiment technical solution of type.
Claims (10)
1. a kind of eyeglass detection and calibration tool, it is characterised in that including:
Eyeglass adjustment frame, for installing eyeglass, can drive the eyeglass in the horizontal plane along the axis perpendicular to the eyeglass
Direction is moved, and the axis direction that can surround the eyeglass rotates the eyeglass;
Locator, for judging the horizontality of eyeglass;
Rangefinder, can move up and down and can be transported along the axis direction level for the eyeglass being installed in the eyeglass adjustment frame
It is dynamic, for reading the optical data of eyeglass.
2. eyeglass detection according to claim 1 and calibration tool, it is characterised in that
The eyeglass adjustment frame includes:
Adjustment frame housing, has through hole;
Locating shaft, through the through hole, is detachably connected by latch assembly with the adjustment frame housing and installation end is set
There is clamping opening.
3. eyeglass detection according to claim 2 and calibration tool, it is characterised in that
The latch assembly includes the first positioner and the second positioner,
First positioner includes clip and locking member, and two free ends of the clip are provided with perforate, the lock
Tight part passes through two perforates to adjust the tightness of clip;
Second positioner offsets through the adjustment frame housing and end with the locating shaft.
4. eyeglass detection according to claim 2 and calibration tool, it is characterised in that
The eyeglass adjustment frame further includes the first sliding equipment, and first sliding equipment includes the first sliding block and the first slide,
First sliding block is connected with the adjustment frame housing, and first sliding block is used to drive the adjustment frame along first slide
It is mobile.
5. eyeglass detection according to claim 1 and calibration tool, it is characterised in that
The locator includes retainer body and locating rod;
The locating rod is connected with the retainer body by telescopic component, and the locating rod is flexible with the telescopic component
Direction is vertical and axial line is perpendicular to the plane where the eyeglass.
6. eyeglass detection according to claim 4 and calibration tool, it is characterised in that
The rangefinder further includes height adjustment mechanism;
The height adjustment mechanism includes fixed frame, the activity framework for being set in the fixed frame, top and the activity
The telescoping rod of the fixed frame is stretched into framework connection and bottom, wherein, the rangefinder is connected with the activity framework.
7. eyeglass detection according to claim 6 and calibration tool, it is characterised in that
The rangefinder further includes the second sliding equipment, and second sliding equipment includes the second sliding block and the second slide, described
Second sliding block is connected by connecting plate with the fixed frame;Second slide extends perpendicularly to first slide
Extending direction.
8. eyeglass detection according to claim 7 and calibration tool, it is characterised in that
The rangefinder further includes driving device, and the driving device acts on the second sliding block of second sliding equipment, uses
Slided in driving second sliding block along second slide.
9. eyeglass detection according to claim 1 and calibration tool, it is characterised in that
The frock is provided with locating shaft and substitutes area, and the locating shaft substitutes the locating shaft that area is preset with multiple and different models.
10. eyeglass detection according to claim 9 and calibration tool, it is characterised in that
Bottom plate is further included, the eyeglass adjustment frame, the locator, the rangefinder, the locating shaft substitute area and be arranged at institute
State the top of bottom plate.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201721081468.3U CN207351659U (en) | 2017-08-25 | 2017-08-25 | Eyeglass detects and calibration tool |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201721081468.3U CN207351659U (en) | 2017-08-25 | 2017-08-25 | Eyeglass detects and calibration tool |
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| Publication Number | Publication Date |
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| CN207351659U true CN207351659U (en) | 2018-05-11 |
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ID=62411858
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| CN201721081468.3U Active CN207351659U (en) | 2017-08-25 | 2017-08-25 | Eyeglass detects and calibration tool |
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Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN107345849A (en) * | 2017-08-25 | 2017-11-14 | 镇江金海创科技有限公司 | Eyeglass detects and calibration tool and method |
| CN108453651A (en) * | 2018-05-24 | 2018-08-28 | 明峰医疗系统股份有限公司 | A kind of pet detector axis positioning tool |
| CN109708850A (en) * | 2018-11-30 | 2019-05-03 | 江西联创电子有限公司 | Multiaxis adjusts detection device |
-
2017
- 2017-08-25 CN CN201721081468.3U patent/CN207351659U/en active Active
Cited By (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN107345849A (en) * | 2017-08-25 | 2017-11-14 | 镇江金海创科技有限公司 | Eyeglass detects and calibration tool and method |
| CN107345849B (en) * | 2017-08-25 | 2023-08-18 | 江苏金海创科技有限公司 | Lens detection and calibration tool and method |
| CN108453651A (en) * | 2018-05-24 | 2018-08-28 | 明峰医疗系统股份有限公司 | A kind of pet detector axis positioning tool |
| CN109708850A (en) * | 2018-11-30 | 2019-05-03 | 江西联创电子有限公司 | Multiaxis adjusts detection device |
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