CN202271233U - Locating device of infrared thermal imager for testing PCB (Printed circuit board) drilling and milling temperature - Google Patents
Locating device of infrared thermal imager for testing PCB (Printed circuit board) drilling and milling temperature Download PDFInfo
- Publication number
- CN202271233U CN202271233U CN 201120373995 CN201120373995U CN202271233U CN 202271233 U CN202271233 U CN 202271233U CN 201120373995 CN201120373995 CN 201120373995 CN 201120373995 U CN201120373995 U CN 201120373995U CN 202271233 U CN202271233 U CN 202271233U
- Authority
- CN
- China
- Prior art keywords
- frame
- positioner
- thermal infrared
- infrared imager
- fixed
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Lifetime
Links
Images
Landscapes
- Radiation Pyrometers (AREA)
Abstract
The utility model discloses a locating device of an infrared thermal imager for testing the PCB (Printed circuit board) drilling and milling temperature. The locating device comprises a fixed mount, a rotary table, an X directional rack, a Y directional rack and a Z directional rack, wherein the fixed mount is connected with any one of the directional racks; the rotary table is fixed on any one of the directional racks; the directional racks as well as the directional racks and the fixed mount can be connected by a regulation device which can cause the directional racks to move in the direction of the regulation device; and the infrared thermal imager can be precisely located in the modes of three-dimensional coordinate locating and planer angle locating. According to the utility model, the infrared thermal imager can be located in the space by three adjustable directional racks, and the locating device has high accuracy and simple locating structure and only needs a simple directional rack framework. The angle of the lens of the infrared thermal imager can be regulated by the rotary table, so that the lens of the infrared thermal imager can accurately aim at the cutter, and therefore, the working temperature of the cutter can be accurately measured.
Description
Technical field
The utility model relates to the machined field, in particular, relates to the thermal infrared imager positioner that a kind of PCB of test bores the milling temperature.
Background technology
In the PCB manufacturing industry, various aperture processing technology though developed, still having the pcb board more than 90% at present is to process through cut.In working angles; The lathe acting converts heat in metal cutting into; These heat in metal cuttings are except that spilling in the surrounding medium on a small quantity, and its waste heat all imports in cutter, smear metal and the pcb board, and cutter, pcb board and lathe temperature rise will speed up tool wear; Damage the PCB internal wiring, when serious even cause that cracking of cutter scraps the pcb board material of processing.
The method of temperature of mensuration cut has a variety of, and is in the existing method, comparatively outstanding with thermal infrared imager.Thermal infrared imager is surveyed the emittance of workpiece (or cutter) surface emissivity unit through optical mechaical scanning mechanism; And convert the emittance of each radiating element into convey electronic video signals; Through signal is handled, show that with the form of visual picture the thermography of demonstration is represented the two-dimensional radiation energy field of measured surface; If the emissivity of radiating element is known, then can obtain the Temperature Distribution field and the dynamic change on radiating element surface through Stefan-Boltzman's law.That the thermal infrared imager thermometry has is directly perceived, easy, can at a distance noncontact monitoring and other advantages, under adverse circumstances, have big superiority during the temperature of measurement object surface.But the camera lens of thermal infrared imager need accurately navigate to detect on the cutter (or workpiece) and just can obtain temperature value more accurately, if in the location, there is error, influence is measured the accuracy of temperature value.
At the PCB manufacture field; Mostly the cutter of processing PCB plate is the carbide alloy min-cutter; It is different that different machining parameters, different machining sheet, different PCB cover plate add the heat that produces man-hour with the carbide alloy min-cutter, adds the man-hour temperature and too highly easily process tool and pcb board are caused adverse effect, so will be particularly important to the monitoring of the real time temperature of min-cutter; For min-cutter, the positioning difficulty of thermal infrared imager is also higher.At present; Thermal infrared imager generally positions through tripod; As shown in Figure 1; The positioner of thermal infrared imager comprises: tripod 15, the bracing frame 16 that is connected through the hinge with tripod 15, and the suspension bracket 17 that is connected through the hinge with bracing frame 16, thermal infrared imager 9 then is fixed on revolving on the platform 7 of linking to each other with suspension bracket 17.The extension of bracing frame 16 and suspension bracket 17 is longer; Locate relatively difficulty through the angle of adjusting bracing frame 16 and suspension bracket 17 and the position of highly realizing thermal infrared imager 9; Machine tool chief axis can be moved in the test process; Thermal infrared imager not only need move the adjustment position, influence locating accuracy, also be difficult to adjustment highly and angle two parameters are cooperatively interacted reach accurate resetting.
The utility model content
A kind of technical problem to be solved of the utility model provides thermal infrared imager positioner and the localization method that a kind of accurately assignment test PCB bores the milling temperature.
The purpose that the utility model test PCB bores the thermal infrared imager positioner of milling temperature realizes through following technical scheme: a kind of PCB of test bores the thermal infrared imager positioner of milling temperature, comprising: fixed mount and revolve platform; Said positioner also comprises: X to frame, Y to frame and Z to three kinds of direction framves of frame; Any is connected in said fixed mount and the direction frame; The said platform that revolves is fixed on the said direction frame, between the said direction frame and between direction frame and the fixed mount through can direction frame mobile adjusting device on its direction being connected.
Preferably, said fixed mount is fixed on the main shaft of tested lathe.Fixed mount is fixed on the machine tool chief axis fixed head, makes whole positioner to move along with machine tool chief axis, to avoid frequent adjustment positioner, reduces workload, increases work efficiency and positioning accuracy.
Preferably, said Y is connected with fixed mount to frame.Said Y direction is merely relative coordinate direction, and direction described in the literary composition is only for referencial use, and Y links to each other with fixed mount to frame, makes the Y can be relative on the Y direction, moving to frame and fixed mount.
Preferably, said Z is connected to frame with Y to frame, and said X is connected to frame with said Z to frame, and the said platform that revolves is fixed on X on frame.Said X, Y, Z direction are merely relative coordinate direction, and direction described in the literary composition is only for referencial use, and Z links to each other to frame with Y to frame; Z can be moved on the Z direction to frame with respect to Y to frame, and X links to each other to frame with Z to frame simultaneously, makes X can move on directions X to frame with respect to Z to frame; And; X to frame receive Y to frame and Z to the pining down of frame, thereby reach moving that three relative directions check and balance, thereby reach three-point fix; Anchor point promptly revolves platform and then is fixed on X on frame, revolves platform and can be accurately positioned in the cutter opposite position on the lathe thereby make.
Preferably, said positioner comprises two said fixed mounts and two corresponding with it same a kind of direction framves.Two fixed mounts can make whole positioner more be tending towards Stability Analysis of Structures, phenomenon such as avoid occurring rocking.
Preferably, said positioner only comprises X that Z that a said fixed mount, Y who links to each other with said fixed mount link to each other to frame to frame, one and said Y links to each other to frame to frame and one and said Z to frame, and the said platform that revolves is fixed on X on frame.When regulating the direction frame, the direction frame on direction moves only need regulate an adjusting device, thereby makes adjusting more accurately, synchronously.
Preferably, the precision of said adjusting device is a micron order.Micron-sized adjusting device makes the adjusting of positioner more accurate.
Preferably, said precision of revolving platform is classification.The platform that revolves of classification makes that the camera lens adjustment of thermal infrared imager is more accurate.
The utility model is owing to realize thermal infrared imager location spatially through three kinds of adjustable direction framves; Promptly respectively through X to frame, Y to frame and Z to frame the moving of three directions in the space respectively, thermal infrared imager can accurately be located corresponding to the position of cutter at the lathe head of a bed accurately, its locate mode is the co-ordinate-type three-point fix; The degree of accuracy is high; And location structure is simple, only needs simple direction frame framework to get final product, and makes the camera lens of thermal infrared imager can adjust angle on the plane through revolving platform; Make the camera lens of thermal infrared imager can aim at cutter accurately, thereby can measure the cutter temperature in when work accurately.
Description of drawings
Fig. 1 is the structure diagram of existing positioner,
Fig. 2 is the topology view of the utility model embodiment one,
Fig. 3 is the topology view of the utility model embodiment two.
Wherein: 1, fixed mount; 2, Y is to adjusting device; 3, Y is to adjusting knob; 4, Z is to adjusting device; 5, Z is to adjusting knob; 6, X is to frame; 7, revolve platform; 8, knob; 9, thermal infrared imager; 10, Z is to frame; 11, X is to adjusting device; 12, X is to adjusting knob; 13, Y is to frame; 15, tripod; 16, bracing frame; 17, suspension bracket.
The specific embodiment
Below in conjunction with accompanying drawing and preferred embodiment the utility model is described further.
The thinking of the utility model is to locate through the three dimensional space coordinate formula; Make thermal infrared imager be in its camera position; And locate through the plane upper angle and to realize adjusting the cutter head that the thermal infrared imager alignment lens bores cutters such as cutter, milling cutter, thereby reach the purpose of accurate positioning shooting.Through this thinking, the utility model provides a kind of positioner of thermal infrared imager, and this positioner can comprise: fixed mount, direction frame and revolve platform; Fixed mount is used for this positioner is fixed; As can fixed mount be fixed on the main shaft fixed head of lathe, so that positioner can move along with the main shaft of lathe, thereby avoid frequent adjustment positioner; Certainly, also can be fixed on outside other position of lathe or the lathe; And the direction frame comprises: X to frame, Y to frame and Z to three kinds of direction framves of frame; The quantity of all kinds of direction framves can be set as required; Connect and moving on this direction through adjusting device between the direction frame, and then each direction frame can both be moved on its direction, reach the effect of space three-point fix; Wherein one type of direction frame is connected through adjusting device with fixed mount, fixes so that the direction frame can move on its direction with whole positioner; Revolve platform and then be fixed on wherein a kind of go up in remaining two kinds of direction framves (the direction frame that promptly is not connected) with fixed mount, so revolve platform can be mobile on its direction along with this direction frame.Thermal infrared imager then is fixed on and revolves on the platform; Along with the direction frame moves on X, Y, three directions of Z; Realize the position location of thermal infrared imager in the space; Simultaneously, the rotation of revolving platform is in one plane rotated thermal infrared imager, so reach the adjustment camera position be the effect of lens direction.
Be illustrated in figure 2 as first kind of embodiment of the utility model, this positioner comprises: fixed mount 1, X to frame 6, Y to frame 13, Z is to frame 10 and revolve platform 7.In the present embodiment; Positioner is fixed on the main shaft of lathe through two fixed mounts 1; So that positioner can move and then avoid repeatedly adjusting positioner along with machine tool chief axis; Two Y in the direction frame are connected to adjusting device 2 through Y with fixed mount 1 respectively to frame 13, so that two Y can move on the Y direction to frame 13; Z is a concave structure frame to frame 10; Its two ends connect to adjusting device 4 to frame 13 logical Z respectively at two Y; And the framework of its two ends through spill link up it, and then the adjusting at two ends all is synchronous, thus make Z to frame 4 can be on the Z direction steadily free from error moving; X is connected to frame with the Z of spill to adjusting device 11 through X to 6 on frame, through regulating X item adjusting device, X is moved on directions X to frame 6.At last, revolve platform be fixed on X on frame along with X moves to frame together, X provides a dogleg section to be used for loading to frame to revolve platform 7, it is terminal that 9 of thermal infrared imagers are fixed on the rotating shaft of revolving platform.The positioning action mode of this positioner is following: at first; Regulate respectively X to adjusting knob 12, Y to adjusting knob 3 and Z to adjusting knob 5; Make X on its direction, move respectively to frame to frame and Z, thereby thermal infrared imager is positioned on the point of the lathe head of a bed corresponding to cutter to frame, Y; Then, adjusting knob 8 is so that the cutter head of the alignment lens cutter of thermal infrared imager 9, thereby reaches the effect of accurate location.
In this embodiment one, Y is vertical bending-like to frame 13 so that provide one with Z to position that frame 10 is connected and Z can be arranged on the Z direction to adjusting device.X provides a dogleg section to be used for loading to frame to revolve platform 7, to make that revolving platform is fixed on X on frame, and makes thermal infrared imager on the ZY plane, have enough spaces to adjust.
Be illustrated in figure 3 as second kind of embodiment of the utility model, different with embodiment one is, present embodiment only needs a fixed mount 1, a Y picture frame 13 and a Z to frame.The benefit of this kind design is; Regulate Y to frame 13 with Z during to frame 10, only need regulate an adjusting device (Y to adjusting device 2 and Z to adjusting device 4), as shown in Figure 1; Adjust Y and need adjust two Y to adjusting device 2 to the position of frame; If generation is asynchronous in adjustment process, be easy to cause error and long-time nonsynchronous adjusting can cause the wearing and tearing of adjusting device, to such an extent as to reduce the precision of adjusting device.But positioner shown in Figure 1 also because of it has two fixed mounts 1, two Y make on its overall structure to frame 10 to the Z of a frame 13 and a spill and more tend towards stability, is difficult for taking place loosening.
In above two embodiment; Employed adjusting device (be X to adjusting device 11, Y to adjusting device 2 and Z to adjusting device 4) is the adjusting device of micron order precision; And revolve the angle regulator that platform is an effectiveness of classification; Through high-precision adjusting device, thereby make the location of positioner reach high-precision location.Said adjusting device comprise a screw mandrel and with the intermeshing nut of said screw mandrel.Described adjusting device is the cooperation of screw mandrel and nut, and the spacing on the screw mandrel is a micron order, and screw mandrel is connected with adjusting knob through bevel gear, through rotating adjusting knob screw mandrel drive nut is moved, and moves thereby drive the direction frame.Said revolve platform comprise the tooth adjusting gear and with the intermeshing driven gear of said adjusting gear.And the said platform that revolves is the gear pair that two adjusting gears and driven gear are meshing with each other and form.
Need to prove that in the utility model, said directions X, Y direction, Z direction and said X are relative coordinate to frame, Y to frame, Z X, Y, Z in frame, are not limited to the coordinate direction shown in the accompanying drawing.Above content is the further explain that combines concrete preferred implementation that the utility model is done, and can not assert that the practical implementation of the utility model is confined to these explanations.For the those of ordinary skill of technical field under the utility model, under the prerequisite that does not break away from the utility model design, can also make some simple deduction or replace, all should be regarded as belonging to the protection domain of the utility model.
Claims (10)
1. test the thermal infrared imager positioner that PCB bores the milling temperature for one kind, comprising: fixed mount and revolve platform; It is characterized in that; Said positioner also comprises: X to frame, Y to frame and Z to three kinds of direction framves of frame; Any is connected in said fixed mount and the direction frame; The said platform that revolves is fixed on the said direction frame, between the said direction frame and between direction frame and the fixed mount through can direction frame mobile adjusting device on its direction being connected.
2. a kind of thermal infrared imager positioner that PCB bores the milling temperature of testing as claimed in claim 1 is characterized in that said fixed mount is fixed on the main shaft fixed head of tested lathe.
3. a kind of thermal infrared imager positioner that PCB bores the milling temperature of testing as claimed in claim 1 is characterized in that said Y is connected with fixed mount to frame.
4. a kind of thermal infrared imager positioner that PCB bores the milling temperature of testing as claimed in claim 3 is characterized in that said Z is connected to frame with Y to frame, and said X is connected to frame with said Z to frame, and the said platform that revolves is fixed on X on frame.
5. a kind of thermal infrared imager positioner that PCB bores the milling temperature of testing as claimed in claim 1 is characterized in that, said positioner comprises two said fixed mounts and two corresponding with it same a kind of direction framves.
6. a kind of thermal infrared imager positioner that PCB bores the milling temperature of testing as claimed in claim 1; It is characterized in that; Said positioner only comprises X that Z that a said fixed mount, Y who links to each other with said fixed mount link to each other to frame to frame, one and said Y links to each other to frame to frame and one and said Z to frame, and the said platform that revolves is fixed on X on frame.
7. a kind of thermal infrared imager positioner that PCB bores the milling temperature of testing as claimed in claim 1 is characterized in that the precision of said adjusting device is a micron order.
8. a kind of thermal infrared imager positioner that PCB bores the milling temperature of testing as claimed in claim 7 is characterized in that, said adjusting device comprise a screw mandrel and with the intermeshing nut of said screw mandrel.
9. a kind of thermal infrared imager positioner that PCB bores the milling temperature of testing as claimed in claim 1 is characterized in that said precision of revolving platform is classification.
10. a kind of thermal infrared imager positioner that PCB bores the milling temperature of testing as claimed in claim 9 is characterized in that, said revolve platform comprise the tooth adjusting gear and with the intermeshing driven gear of said adjusting gear.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN 201120373995 CN202271233U (en) | 2011-09-30 | 2011-09-30 | Locating device of infrared thermal imager for testing PCB (Printed circuit board) drilling and milling temperature |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN 201120373995 CN202271233U (en) | 2011-09-30 | 2011-09-30 | Locating device of infrared thermal imager for testing PCB (Printed circuit board) drilling and milling temperature |
Publications (1)
Publication Number | Publication Date |
---|---|
CN202271233U true CN202271233U (en) | 2012-06-13 |
Family
ID=46191619
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN 201120373995 Expired - Lifetime CN202271233U (en) | 2011-09-30 | 2011-09-30 | Locating device of infrared thermal imager for testing PCB (Printed circuit board) drilling and milling temperature |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN202271233U (en) |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102501144A (en) * | 2011-09-30 | 2012-06-20 | 深圳市金洲精工科技股份有限公司 | Positioning device and positioning method of thermal infrared imager for testing drilling and milling temperature of PCBs (printed circuit boards) |
-
2011
- 2011-09-30 CN CN 201120373995 patent/CN202271233U/en not_active Expired - Lifetime
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102501144A (en) * | 2011-09-30 | 2012-06-20 | 深圳市金洲精工科技股份有限公司 | Positioning device and positioning method of thermal infrared imager for testing drilling and milling temperature of PCBs (printed circuit boards) |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
CN102501144A (en) | Positioning device and positioning method of thermal infrared imager for testing drilling and milling temperature of PCBs (printed circuit boards) | |
CN102072877B (en) | System and method for measuring residual stress in real time | |
CN104647041B (en) | Small-scale numerically-controlled milling and drilling machine and correction and tool alignment method thereof | |
CN105004515B (en) | Hydrostatic spindle kinematic accuracy on-line testing method based on dynamic Laser interferometer | |
CN106736849B (en) | Micro-diameter milling tool active probe formula high-precision tool setting device and method | |
CN102768028A (en) | Method and device for online in-situ measurement with single joint arm | |
CN113523901A (en) | Precision detection method for five-axis machine tool | |
CN104596422A (en) | Portable detector of CNC milling machine cutter | |
CN103894883A (en) | Cutter deformation measuring fixture and cutter deformation online measuring method implemented by same | |
CN103448155B (en) | Angle regulation system used for slicer | |
CN109737884A (en) | A kind of quiet dynamic deformation amount on-Line Monitor Device of axial workpiece and method | |
CN206683593U (en) | Measured workpiece dimensional gaughing equipment based on 3D machine vision | |
CN102735191A (en) | Device for determining verticality of honeycomb ceramics | |
WO2011156941A1 (en) | Method for realizing the spatial transformation from machining points to reference points of installation survey | |
CN202271233U (en) | Locating device of infrared thermal imager for testing PCB (Printed circuit board) drilling and milling temperature | |
CN106514432A (en) | Detection tool and method for detecting geometric accuracy of spindle axis of precision numerical control machine tool | |
CN100496839C (en) | Fixture with capacity of automatically regulating parallelism of sparker plane and workpiece plane | |
Surkov | Development of methods and means of coordinate measurements for linear and angular parameters of cutting instruments | |
CN103419091A (en) | Support for adjusting laser displacement sensor with multiple freedom degrees | |
CN202656010U (en) | Contactless two-way on-line sighting and positioning system for five-axis machining center | |
CN103522127A (en) | On-machine measuring device and method for rotary curve contour machining | |
CN109352423A (en) | Numerically-controlled machine tool AB pivot angle accuracy detection tooling and detection method | |
CN203993543U (en) | A kind of abrasive power high precision measuring device | |
CN102927904A (en) | Cutter measurement device | |
CN207730448U (en) | Gear hobbing machine worktable test platform |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
CX01 | Expiry of patent term |
Granted publication date: 20120613 |
|
CX01 | Expiry of patent term |