CN202886935U - Numerical control machining machine tool of ceramic plaster mold - Google Patents
Numerical control machining machine tool of ceramic plaster mold Download PDFInfo
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- CN202886935U CN202886935U CN 201220580295 CN201220580295U CN202886935U CN 202886935 U CN202886935 U CN 202886935U CN 201220580295 CN201220580295 CN 201220580295 CN 201220580295 U CN201220580295 U CN 201220580295U CN 202886935 U CN202886935 U CN 202886935U
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- machining machine
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Abstract
The utility model discloses a numerical control machining machine tool of a ceramic plaster mold. The numerical control machining machine tool comprises a three-dimensional scanner, a professional three-dimensional command signal generating computer, a control cabinet and a machining machine tool, wherein the three-dimensional scanner is provided with two cameras which have a certain included angle, a plurality of frames of specifically coded structure light projected by adopting a grating reaches an object to be detected, and corresponding image signals are synchronously acquired, and are input to the professional three-dimensional command signal generating computer to generate three-dimensional data signals after being processed by adopting the professional three-dimensional command signal generating computer, the three-dimensional data signals are output to the control cabinet, and the control cabinet controls the machining machine tool for carrying out three-dimensional works. According to the utility model, the mode that the original portal frame slides along a working platform is changed into a mode that the working platform slides and the portal frame is fixed; and a main shaft moves left and right as well as up and down, a main shaft head and a rotating disk can rotate together in a reciprocating manner in 210-DEG; and a cutter base can rotate in a reciprocating manner in 240-DEG. Due to the movement and rotation, the rotating angle and space of a cutter are increased, and thus the production efficiency is increased and the convenience is brought for machining. The numerical control machining machine tool is mainly used in the machining industry of the ceramic plaster mold.
Description
Technical field:
The utility model relates to ceramic gypsum mold production equipment technical field, utilizes spatial digitizer to obtain 3-D view to process through professional software, flow to the numerically controlled processing equipment that numerically-controlled machine carries out ceramic gypsum Mould Machining more specifically to a kind of.
Background technology:
Chinese patent ZL201020289256.6 discloses a kind of ceramic gypsum die numerical control system of processing structure-improved, and its weak point is: 1, because its portal frame is larger, in actual production process, the mobile gantry frame is very inconvenient.2, add that directly to be with cutter to carry out the Mould Machining movement angle by main shaft man-hour less, so that the production and processing precision is not high enough, efficient is low.
The utility model content:
The purpose of this utility model is exactly the deficiency for prior art, and ceramic gypsum die numerical control machining tool is provided, and it has improved production efficiency, and design more rationally improves machining precision, and it is more convenient easy to operate.
Technology solution of the present utility model is as follows:
Pottery gypsum die numerical control machining tool generates computer, switch board and machining tool by spatial digitizer, professional three-dimensional command signal and forms the work of switch board output signal controlled working lathe.Spatial digitizer has two cameras that form an angle, the structured light that adopts optical grating projection to count width of cloth specific coding shines on the object under test, adopt synchronously to get the respective image signal, this picture signal is inputted professional three-dimensional command signal and is generated computer generation 3 D stereo data-signal after the three-dimensional command signal of specialty generates the computer processing, the 3 D stereo data-signal is exported to switch board, drives machining tool and carries out 3 D stereo work; Machining tool is by being comprised of portal frame, pedestal, worktable, main shaft, rotating disk, main tapping and the base of tool, and portal frame is installed on the pedestal and maintains static, and worktable is installed on the guide rail on the pedestal, and worktable moves forward and backward along Y direction; Main shaft is installed on the movable block of crossbeam of portal frame, and main shaft is along the X-direction move left and right, and main shaft moves up and down along Z-direction; Rotating disk is installed in the main shaft lower end, and main tapping is installed on the rotating disk, and main tapping and rotating disk are done along contrary 210 ° of rotations along Z axis; The base of tool is installed on the main tapping, and the base of tool is done along contrary 240 ° of rotations along X-axis.
The beneficial effects of the utility model are:
1, it changes original portal frame into worktable along movable workbench and moves along portal frame and since portal frame heavier during along the worktable slide energy consumption large, it is also convenient not to operate.
2, increase the anglec of rotation and the space of cutter by the rotation of main tapping and the base of tool, thereby improved the production and processing precision, improved work efficiency, brought facility to processing.
Description of drawings:
Fig. 1 is structural representation of the present utility model
Embodiment:
Embodiment: ceramic gypsum die numerical control machining tool structural representation as shown in Figure 1, by spatial digitizer 1, the three-dimensional command signal of specialty generates computer 2, switch board 3 and machining tool 4 form, 4 work of switch board 3 output signal controlled working lathes, spatial digitizer 1 has two cameras 11 that form an angle, the structured light that adopts optical grating projection to count width of cloth specific coding shines on the object under test, adopt synchronously to get the respective image signal, this picture signal is inputted professional three-dimensional command signal and is generated computer 2 generation 3 D stereo data-signal after the three-dimensional command signal of specialty generates computer 2 processing, the 3 D stereo data-signal is exported to switch board 3, drives machining tool 4 and carries out 3 D stereo work;
Machining tool 4 is comprised of portal frame 41, pedestal 42, worktable 43, main shaft 44, rotating disk 45, main tapping 46 and the base of tool 47, portal frame 41 is installed on the pedestal 42 and maintains static, worktable 43 is installed on the guide rail 421 on the pedestal 42, and worktable 43 moves forward and backward along Y direction; Main shaft 44 is installed on the movable block 412 of crossbeam 411 of portal frame 41, and main shaft 44 is along the X-direction move left and right, and main shaft 44 moves up and down along Z-direction; Rotating disk 45 is installed in main shaft 44 lower ends, and main tapping 46 is installed on the rotating disk 45, and main tapping 46 is done along contrary 210 ° of rotations along Z axis with rotating disk 45; The base of tool 47 is installed on the main tapping 46, and the base of tool 47 is done along contrary 240 ° of rotations along X-axis; Cutter 48 is installed on the motor shaft of the base of tool 47.
Process, for example to the processing of mould side, the work of empty cabinet controlled working lathe processed, movable workbench the mold movement on the worktable under portal frame, movable block move left and right main shaft on the portal frame crossbeam is to corresponding mould side, main shaft moves down main tapping again to the mould side, the dial rotation main tapping makes the base of tool face toward the side of mould, the side that the base of tool turns an angle and makes cutter paste mould makes the rotation of the movement of worktable, movable block and main shaft and rotating disk and the base of tool realize processing to the mould side pose at last.
Claims (1)
1. ceramic gypsum die numerical control machining tool, by spatial digitizer (1), the three-dimensional command signal of specialty generates computer (2), switch board (3) and machining tool (4) form, switch board (3) output signal control lathe (4) work, spatial digitizer (1) has two cameras (11) that form an angle, the structured light that adopts optical grating projection to count width of cloth specific coding shines on the object under test, adopt synchronously to get the respective image signal, this picture signal is inputted professional three-dimensional command signal and is generated computer (2) and generate through the three-dimensional command signal of specialty and produce the 3 D stereo data-signal after computer (2) is processed, and the 3 D stereo data-signal is exported to switch board (3) drive and added lathe (4) and carry out 3 D stereo work; It is characterized in that:
Machining tool (4) is comprised of portal frame (41), pedestal (42), worktable (43) main shaft (44), rotating disk (45), main tapping (46) and the base of tool (47), portal frame (41) is installed on the pedestal (42) and maintains static, worktable (43) is installed on the guide rail (421) on the pedestal (42), and worktable (43) moves forward and backward along Y direction; Main shaft (44) is installed on the movable block (412) of crossbeam (411) of portal frame (41), and main shaft (44) is along the X-direction move left and right, and main shaft (44) moves up and down along Z-direction; Rotating disk (45) is installed in main shaft (44) lower end, and main tapping (46) is installed on the rotating disk (45), and main tapping (46) is done along contrary 210 ° of rotations along Z axis with rotating disk (45); The base of tool (47) is installed on the main tapping (46), and the base of tool (47) is done along contrary 240 ° of rotations along X-axis.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN 201220580295 CN202886935U (en) | 2012-11-06 | 2012-11-06 | Numerical control machining machine tool of ceramic plaster mold |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN 201220580295 CN202886935U (en) | 2012-11-06 | 2012-11-06 | Numerical control machining machine tool of ceramic plaster mold |
Publications (1)
Publication Number | Publication Date |
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CN202886935U true CN202886935U (en) | 2013-04-17 |
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Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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CN 201220580295 Expired - Fee Related CN202886935U (en) | 2012-11-06 | 2012-11-06 | Numerical control machining machine tool of ceramic plaster mold |
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CN (1) | CN202886935U (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN107255447A (en) * | 2017-08-09 | 2017-10-17 | 广东秦泰盛智能化科技有限公司 | A kind of 3D projection scannings test equipment |
CN114518078A (en) * | 2022-03-18 | 2022-05-20 | 南京航空航天大学 | Gantry type structure optical scanning robot and method for measuring surface topography of large equipment |
-
2012
- 2012-11-06 CN CN 201220580295 patent/CN202886935U/en not_active Expired - Fee Related
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN107255447A (en) * | 2017-08-09 | 2017-10-17 | 广东秦泰盛智能化科技有限公司 | A kind of 3D projection scannings test equipment |
CN107255447B (en) * | 2017-08-09 | 2024-01-30 | 广东秦泰盛智能化科技有限公司 | 3D projection scanning test equipment |
CN114518078A (en) * | 2022-03-18 | 2022-05-20 | 南京航空航天大学 | Gantry type structure optical scanning robot and method for measuring surface topography of large equipment |
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Legal Events
Date | Code | Title | Description |
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C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20130417 Termination date: 20141106 |
|
EXPY | Termination of patent right or utility model |