CN107825144A - A kind of fiberglass-reinforced glass storage tank, tower numerical control boring device - Google Patents
A kind of fiberglass-reinforced glass storage tank, tower numerical control boring device Download PDFInfo
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- CN107825144A CN107825144A CN201711259652.7A CN201711259652A CN107825144A CN 107825144 A CN107825144 A CN 107825144A CN 201711259652 A CN201711259652 A CN 201711259652A CN 107825144 A CN107825144 A CN 107825144A
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- main shaft
- processing platform
- servomotor
- storage tank
- fiberglass
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23P—METAL-WORKING NOT OTHERWISE PROVIDED FOR; COMBINED OPERATIONS; UNIVERSAL MACHINE TOOLS
- B23P23/00—Machines or arrangements of machines for performing specified combinations of different metal-working operations not covered by a single other subclass
- B23P23/04—Machines or arrangements of machines for performing specified combinations of different metal-working operations not covered by a single other subclass for both machining and other metal-working operations
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B23—MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
- B23Q—DETAILS, COMPONENTS, OR ACCESSORIES FOR MACHINE TOOLS, e.g. ARRANGEMENTS FOR COPYING OR CONTROLLING; MACHINE TOOLS IN GENERAL CHARACTERISED BY THE CONSTRUCTION OF PARTICULAR DETAILS OR COMPONENTS; COMBINATIONS OR ASSOCIATIONS OF METAL-WORKING MACHINES, NOT DIRECTED TO A PARTICULAR RESULT
- B23Q11/00—Accessories fitted to machine tools for keeping tools or parts of the machine in good working condition or for cooling work; Safety devices specially combined with or arranged in, or specially adapted for use in connection with, machine tools
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P70/00—Climate change mitigation technologies in the production process for final industrial or consumer products
- Y02P70/10—Greenhouse gas [GHG] capture, material saving, heat recovery or other energy efficient measures, e.g. motor control, characterised by manufacturing processes, e.g. for rolling metal or metal working
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- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- Physics & Mathematics (AREA)
- Optics & Photonics (AREA)
- Grinding And Polishing Of Tertiary Curved Surfaces And Surfaces With Complex Shapes (AREA)
- Drilling And Boring (AREA)
Abstract
A kind of fiberglass-reinforced glass storage tank, tower numerical control boring device.It includes main shaft headstock, spindle servo electric machine, main shaft reductor, main shaft, assembling support ring, main shaft tailstock case, bearing block, processing platform lathe bed, linear slide rail, rack, processing platform, processing platform servomotor, processing platform reductor, linear module, linear module servomotor, linear slide, telescopic arm, electro spindle and control system.Fiberglass-reinforced glass storage tank provided by the invention, tower numerical control boring device have the advantages that:1st, all operationss are controlled by control system and completed, therefore position more accurate, reduction error;2nd, automaticity is high, therefore can effectively reduce recruitment number, reduces the labor intensity and production cost of operating personnel;Operating efficiency is 5 10 times of traditional mode;3rd, automatic dust absorption, can prevent the pollution of the environment and the personal injury to operator.
Description
Technical field
The invention belongs to glass steel making servicing unit technical field, more particularly to a kind of fiberglass-reinforced glass storage tank, tower number
Control boring device.
Background technology
With the development of society, the frequent flowing of staff turns into normality, be often lost in a skilled worker for
All it is an invisible wealth loss for enterprise, only for fiberglass industry, probably needs half a year left from apprentice to finishing one's apprenticeship
The right time, therefore it is often related to product quality decline to recruit the consequence that new worker brings.In addition, the production of every product all needs
To pass through the processes such as processing, the polishing of several workers to complete, not only low production efficiency, and everyone gimmick, eye
It is different, therefore the same batch products for eventually making to dispatch from the factory have difference slightly.In addition, perforate is carried out on every product
All it is to be measured by worker with the mode of measurer and naked eyes, thus easily produces error, sometimes a minimum deviation is just
Installation or service life that can be to product cause greatly to damage, and as a result cause deleterious effect to enterprise.In addition, with me
The increase of state's per capita income, growth in the living standard, cost of labor go up year after year, it has also become a undisputable fact.
The content of the invention
In order to solve the above problems, it is an object of the invention to provide a kind of fiberglass-reinforced glass storage tank, tower numerical control boring device.
In order to achieve the above object, fiberglass-reinforced glass storage tank provided by the invention, tower numerical control boring device include the main shaft head of a bed
Case, spindle servo electric machine, main shaft reductor, main shaft, assembling support ring, main shaft tailstock case, bearing block, processing platform lathe bed, line
Property slide rail, rack, processing platform, processing platform servomotor, processing platform reductor, linear module, linear module servo electricity
Machine, linear slide, telescopic arm, electro spindle and control system;Wherein main shaft headstock and main shaft tailstock case is horizontally-opposed;Main shaft is watched
Take the top surface that motor is arranged on main shaft headstock;The input of main shaft reductor and the output axis connection of spindle servo electric machine, it is defeated
Go out and a main shaft is installed on end;Another main shaft is installed on the top surface of main shaft tailstock case, and two main shaft phases by bearing block
Setting and axle center are located on same horizontal line;The outer end of every main shaft install respectively one be used for be loaded fiberglass-reinforced glass storage tank,
The assembling support ring of workpiece including tower;Processing platform lathe bed is located at the side of main shaft headstock and main shaft tailstock case;Two groups
Axial direction of the linear slide rail along main shaft 4 is separately mounted to the top surface both sides position of processing platform lathe bed;Rack with linear slide rail to put down
Capable mode is arranged on the inside line of any group of linear slide rail on processing platform lathe bed top surface;Processing platform passes through positioned at bottom surface
The linear slide block of both sides is movably installed on two groups of linear slide rails;It is flat that processing platform servomotor is arranged on processing
Surface one end of platform, output shaft are connected with the input of processing platform reductor, pacify in the output end of processing platform reductor
Equipped with the clearance elimination gear being meshed with rack, therefore by processing platform servomotor processing platform can be driven to move left and right;
Linear module is arranged on the surface middle part of processing platform;Linear module servomotor is arranged on the front end of linear module;It is linear sliding
Block is arranged on linear module surface in a manner of energy edge is moved perpendicular to major axes orientation, and defeated with linear module servomotor
Shaft is connected, therefore by linear module servomotor linear slide block can be driven to move forward and backward;One end installation of telescopic arm
On linear slide block, the other end extands rearward to outside processing platform lathe bed and is provided with electro spindle on the end, and electro spindle is used for
Cutter is installed;Set-up of control system on the outside of processing platform lathe bed, and with spindle servo electric machine, processing platform servomotor,
Linear module servomotor and electro spindle electrical connection.
Described fiberglass-reinforced glass storage tank, tower numerical control boring device also include a fiber bag precipitator, fiber bag precipitator
On processing platform, suction port is arranged on electro spindle by flexible pipe, for removing caused dust in process, and
And fiber bag precipitator electrically connects with control system.
Described fiberglass-reinforced glass storage tank, tower numerical control boring device also include workpiece support device, described workpiece support dress
Put including long rails, circumferential track and multiple work supports;Wherein long rails are arranged in two masters along major axes orientation
Directly over workpiece between axle;Circumferential track is semicircle of the opening under, and top is fixed in a movable manner at center
On the bottom surface of long rails, inner surface is stuck on the top outer circumference surface of workpiece;The lower end of work support is provided with roller, multiple
Work support is divided into the bottom cylindrical side face both sides position that two row are supported on workpiece.
Fiberglass-reinforced glass storage tank provided by the invention, tower numerical control boring device have the advantages that:
1st, all operationss are controlled by control system and completed, therefore position more accurate, reduction error;
2nd, automaticity is high, therefore can effectively reduce recruitment number, reduces labor intensity and the production of operating personnel
Cost;Operating efficiency is 5-10 times of traditional mode;
3rd, automatic dust absorption, can prevent the pollution of the environment and the personal injury to operator.
Brief description of the drawings
Fig. 1 is fiberglass-reinforced glass storage tank provided by the invention, tower numerical control boring device structural perspective.
Fig. 2 is workpiece support device front view in fiberglass-reinforced glass storage tank provided by the invention, tower numerical control boring device.
Fig. 3 is workpiece support device top view in fiberglass-reinforced glass storage tank provided by the invention, tower numerical control boring device.
Fig. 4 is workpiece support device side view in fiberglass-reinforced glass storage tank provided by the invention, tower numerical control boring device.
Embodiment
Fiberglass-reinforced glass storage tank provided by the invention, tower numerical control boring device are carried out with specific embodiment below in conjunction with the accompanying drawings
Describe in detail.
As shown in Fig. 1-Fig. 4, fiberglass-reinforced glass storage tank provided by the invention, tower numerical control boring device include main shaft headstock
1st, spindle servo electric machine 2, main shaft reductor 3, main shaft 4, assembling support ring 5, main shaft tailstock case 6, bearing block 7, processing platform bed
Body 8, linear slide rail 9, rack 10, processing platform 11, processing platform servomotor 12, processing platform reductor 13, linear module
14th, linear module servomotor 15, linear slide 16, telescopic arm 17, electro spindle 18 and control system 20;Wherein main shaft headstock
1 and main shaft tailstock case 6 it is horizontally-opposed;Spindle servo electric machine 2 is arranged on the top surface of main shaft headstock 1;The input of main shaft reductor 3
The output axis connection with spindle servo electric machine 2 is held, a main shaft 4 is installed in output end;Another main shaft 4 is pacified by bearing block 7
Top surface loaded on main shaft tailstock case 6, and two main shafts 4 are oppositely arranged and axle center is located on same horizontal line;Every main shaft 4
Outer end the assembling support ring 5 of one workpiece including fiberglass-reinforced glass storage tank, tower that is used to being loaded is installed respectively;Processing platform lathe bed
8 positioned at the side of main shaft headstock 1 and main shaft tailstock case 6;Axial direction of two groups of linear slide rails 9 along main shaft 4 is separately mounted to process
The top surface both sides position of platform lathe bed 8;Rack 10 is arranged on the top surface of processing platform lathe bed 8 in a manner of parallel with linear slide rail 9
The inside line of upper any group of linear slide rail 9;Processing platform 11 is by the linear slide block positioned at bottom surface both sides with moveable side
Formula is arranged on two groups of linear slide rails 9;Processing platform servomotor 12 be arranged on processing platform 11 surface one end, output shaft with
The input of processing platform reductor 13 is connected, and is provided with the output end of processing platform reductor 13 and is meshed with rack 10
Clearance elimination gear, therefore can by processing platform servomotor 12 drive processing platform 11 move left and right;Linear module 14 is pacified
Mounted in the surface middle part of processing platform 11;Linear module servomotor 15 is arranged on the front end of linear module 14;Linear slide block 16
By can along being arranged on the linear surface of module 14 in a manner of being moved perpendicular to the direction of main shaft 4, and with linear module servomotor 15
Output shaft be connected, therefore by linear module servomotor 15 linear slide block 16 can be driven movable;Telescopic arm 17
One end be arranged on linear slide block 16, the other end extands rearward on the outside of processing platform lathe bed 8 and the end and is provided with electric master
Axle 18, electro spindle 18 are used to install cutter;Control system 20 is arranged on the outside of processing platform lathe bed 8, and electric with main axle servo
Machine 2, processing platform servomotor 12, linear module servomotor 15 and electro spindle 18 electrically connect.
Described fiberglass-reinforced glass storage tank, tower numerical control boring device also include a fiber bag precipitator 19, cloth-sack-type dust removal
Device 19 is arranged on processing platform 11, and suction port is arranged on electro spindle 18 by flexible pipe, is produced for removing in process
Dust, and fiber bag precipitator 19 electrically connects with control system 20.
Described fiberglass-reinforced glass storage tank, tower numerical control boring device also include workpiece support device, described workpiece support dress
Put including long rails 21, circumferential track 22 and multiple work supports 23;Wherein long rails 21 are set in place along the direction of main shaft 4
Directly over workpiece 24 between two main shafts 4;Circumferential track 22 is semicircle of the opening under, and top center is sentenced removable
Mode be fixed on the bottom surface of long rails 21, inner surface is stuck on the top outer circumference surface of workpiece 24;Work support 23
Lower end is provided with roller, and multiple work supports 23 are divided into the bottom cylindrical side face both sides position that two row are supported on workpiece 24.
Now the application method of fiberglass-reinforced glass storage tank provided by the invention, tower numerical control boring device is described below:
First, the workpiece 24 of perforate processing, such as the both ends of fiberglass-reinforced glass storage tank or tower dress will need to be carried out by operator
It is stuck in two assembling support rings 5;Circumferential track 22 is stuck on the top outer circumference surface of workpiece 24 from opening simultaneously, bottom
Outer circumference surface both sides position is supported with two row work supports 23 respectively;
Second, opening control system 20, and work pieces process datum mark is set in man-machine interface thereon, including:1. work
The length standard point of the angle reference point of part direction of rotation, 2. axial direction, be generally arranged at the workpiece left side, 3. radial direction
Radial reference point, is generally arranged at outer surface of workpiece.Then manually adjust workpiece and rotate main shaft 4, and make electro spindle 18 right
Length standard point and radial reference point on quasi- workpiece, machining benchmark point of this position as electro spindle 18;
3rd, according to processing drawing requirement, machining information is inputted in the man-machine interface of control system 20, including 1. workpiece is straight
Footpath, 2. workpiece, the 3. blowing angle in each hole, 4. perforate axial location, 5. perforate radius, radius of 6. being polished outside hole;
4th, open fiber bag precipitator 19;
5th, automatic perforate.Illustrated by taking following parameter perforate processing as an example:Diameter of work 2500mm, wall thickness 30mm,
60 degree of blowing angle, perforate axial location 1000mm, perforate radius 200mm, polish outside hole radius 250mm.On electro spindle 18
Perforate milling cutter is installed, makes the length standard point and radial reference point of its cutter head alignment pieces 24, opens automatic orifice pattern,
Make the snapback 200mm of telescopic arm 17 to home under the driving of linear module servomotor 15;Start electro spindle 18, in master
Rotate main shaft 4 and workpiece 24 under the driving of axle servomotor 2, until workpiece 24 is positioned at 60 degree of positions;Watched in processing platform
Take makes processing platform 11 be moved right along linear slide rail 9 under the driving of motor 12, until 1000mm perforate home positions are positioned at,
Then processing platform 11 is moved to the left 200mm, be positioned at perforate radial location;Then in the drive of linear module servomotor 15
Make the fast feed 200mm of telescopic arm 17 under dynamic, until cutter head thereon reaches the surface of workpiece 24, then telescopic arm 17 is with the speed that works
Degree feeding 30mm, makes cutter head penetrate the tube wall of workpiece 24.At the same time, the rotation of main shaft 4 and processing platform 11 is made to move left and right simultaneously
Carry out, concretely comprise the following steps:1. first, main shaft 4 rotates forward to the direction of electro spindle 18, while processing platform 11 moves right
200mm, thus cut the circular arc of upper left 1/4 that portals;2. main shaft 4 reversely rotates, while processing platform 11 continues to move right
200mm, thus cut the circular arc of upper right 1/4 that portals;3. main shaft 4 continues to reversely rotate, while processing platform 11 is moved to the left
200mm, thus cut the circular arc of bottom right 1/4 that portals;4. main shaft 4 rotates forward, while processing platform 11 continues to be moved to the left
200mm, thus cut the circular arc of lower-left 1/4 that portals.Then the snapback 230mm of telescopic arm 17 adds to home, this hole perforate
Work is completed.Main shaft 4 rotates the blowing angle for making workpiece 24 be positioned at next hole afterwards, and processing platform 11 moves right and is positioned at
The axial location in next hole, repeat said process and carry out the perforate processing in next hole, the perforate work until completing each hole.
After machining, electro spindle 18 stops operating and returns to machining benchmark point, dismantles lower perforate milling cutter;
6th, the chamfering in hole.Angle cutting tool is installed on electro spindle 18, makes the length standard of its cutter head alignment pieces 24
Point and radial reference point.Automatic chamfering pattern is opened, the chamfering that each hole is completed according to the process of previous step works.Process
Cheng Hou, electro spindle 18 stop operating and return to machining benchmark point, dismantle lower angle cutting tool;
7th, the polishing of hole outer surface.Polishing bistrique is installed on electro spindle 18, and makes the length of bistrique alignment pieces 24
Datum mark and radial reference point, automatically grinding pattern is opened, makes telescopic arm 17 fast under the driving of linear module servomotor 15
Speed retraction 200mm is to home;Start electro spindle 18, revolve main shaft 4 and workpiece 24 under the driving of spindle servo electric machine 2
Turn, until workpiece 24 is positioned at 60 degree of positions;Processing platform 11 is set to be slided along linear under the driving of processing platform servomotor 12
Rail 9 moves right, until being positioned at 1000mm perforate home positions, processing platform 11 is moved to the left 250mm, is positioned at
Polishing radial location;Then the fast feed 200mm of telescopic arm 17 is made under the driving of linear module servomotor 15, until thereon
Cutter head reach workpiece surface, then telescopic arm 17 with operating rate feed 1mm, make bistrique contact workpiece tube wall.At the same time,
The rotation of main shaft 4 and processing platform 11 is moved left and right while is carried out, concretely comprise the following steps:1. first, main shaft 4 is to the direction of electro spindle 18
Rotate forward, while processing platform 11 moves right 250mm, the circular arc sector of hole upper left 1/4 of thus polishing;2. main shaft 4 is reverse
Rotation, while processing platform 11 continues the 250mm that moves right, the circular arc sector of hole upper right 1/4 of thus polishing;3. main shaft 4 continues instead
To rotation, while processing platform 11 is moved to the left 250mm, the circular arc sector of hole bottom right 1/4 of thus polishing;4. main shaft 4 rotates forward,
Processing platform 11 continues to be moved to the left 250mm simultaneously, the circular arc sector of hole lower-left 1/4 of thus polishing.Then telescopic arm 17 quickly returns
Contracting 201mm machines to home, the polishing of this hole outer surface.The rotation of main shaft 4 afterwards makes workpiece 24 be positioned at next hole
Grinding angle, processing platform 11 move right and are positioned at the axial location in next hole, repeat said process and carry out next hole
Outer surface polishing processing, the outer surface until completing each hole is polished work.After machining, electro spindle 18 stops operating simultaneously
Return to machining benchmark point;
8th, close fiber bag precipitator 19;
9th, the workpiece 24 machined is pulled down from assembling support ring 5;
Tenth, the step of repeating first to the 9th, carry out the processing of next workpiece 24.
Claims (3)
1. a kind of fiberglass-reinforced glass storage tank, tower numerical control boring device, it is characterised in that:Described fiberglass-reinforced glass storage tank, tower numerical control are opened
Aperture apparatus include main shaft headstock (1), spindle servo electric machine (2), main shaft reductor (3), main shaft (4), assembling support ring (5),
Main shaft tailstock case (6), bearing block (7), processing platform lathe bed (8), linear slide rail (9), rack (10), processing platform (11), plus
It is work platform servomotor (12), processing platform reductor (13), linear module (14), linear module servomotor (15), linear
Sliding block (16), telescopic arm (17), electro spindle (18) and control system (20);Wherein main shaft headstock (1) and main shaft tailstock case (6)
It is horizontally-opposed;Spindle servo electric machine (2) is arranged on the top surface of main shaft headstock (1);The input and main shaft of main shaft reductor (3)
The output axis connection of servomotor (2), a main shaft (4) is installed in output end;Another main shaft (4) is pacified by bearing block (7)
Top surface loaded on main shaft tailstock case (6), and two main shafts (4) are oppositely arranged and axle center is located on same horizontal line;Every
The outer end of main shaft (4) is installed by one assembling support ring (5) for the workpiece including be loaded fiberglass-reinforced glass storage tank, tower respectively;Add
Work platform lathe bed (8) is located at the side of main shaft headstock (1) and main shaft tailstock case (6);Two groups of linear slide rails (9) are along main shaft (4)
Axial direction be separately mounted to the top surface both sides position of processing platform lathe bed (8);Rack (10) is with the side parallel with linear slide rail (9)
Formula is arranged on the inside line of any group of linear slide rail (9) on processing platform lathe bed (8) top surface;Processing platform (11) by positioned at
The linear slide block of bottom surface both sides is movably installed on two groups of linear slide rails (9);Processing platform servomotor (12)
Installed in surface one end of processing platform (11), output shaft is connected with the input of processing platform reductor (13), and processing is flat
The clearance elimination gear being meshed with rack (10) is installed in the output end of platform reductor (13), therefore can be watched by processing platform
Motor (12) driving processing platform (11) is taken to move left and right;Linear module (14) is arranged on the surface middle part of processing platform (11);
Linear module servomotor (15) is arranged on the front end of linear module (14);Linear slide block (16) is with energy along perpendicular to main shaft (4)
The mode of direction movement is arranged on linear module (14) surface, and is connected with the output shaft of linear module servomotor (15)
Connect, therefore by linear module servomotor (15) linear slide block (16) can be driven movable;One end of telescopic arm (17)
On linear slide block (16), the other end extands rearward on processing platform lathe bed (8) outside and the end and is provided with electro spindle
(18), electro spindle (18) is used to install cutter;Control system (20) is arranged on the outside of processing platform lathe bed (8), and and main shaft
Servomotor (2), processing platform servomotor (12), linear module servomotor (15) and electro spindle (18) electrical connection.
2. fiberglass-reinforced glass storage tank according to claim 1, tower numerical control boring device, it is characterised in that:Described fiberglass
Storage tank, tower numerical control boring device also include a fiber bag precipitator (19), and it is flat that fiber bag precipitator (19) is arranged on processing
On platform (11), suction port is arranged on electro spindle (18) by flexible pipe, for removing caused dust in process, and cloth
Sack cleaner (19) electrically connects with control system (20).
3. fiberglass-reinforced glass storage tank according to claim 1, tower numerical control boring device, it is characterised in that:Described fiberglass
Storage tank, tower numerical control boring device also include workpiece support device, and described workpiece support device includes long rails (21), week
To track (22) and multiple work supports (23);Wherein long rails (21) are arranged in two main shafts along main shaft (4) direction
(4) directly over the workpiece (24) between;Circumferential track (22) is semicircle of the opening under, and moveable side is sentenced at top center
Formula is fixed on the bottom surface of long rails (21), and inner surface is stuck on the top outer circumference surface of workpiece (24);Work support (23)
Lower end roller is installed, multiple work supports (23) are divided into the bottom cylindrical side face both sides that two row are supported on workpiece (24)
Position.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN201711259652.7A CN107825144B (en) | 2017-12-04 | 2017-12-04 | Numerical control perforating device for glass fiber reinforced plastic storage tank and tower |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN201711259652.7A CN107825144B (en) | 2017-12-04 | 2017-12-04 | Numerical control perforating device for glass fiber reinforced plastic storage tank and tower |
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Publication Number | Publication Date |
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CN107825144A true CN107825144A (en) | 2018-03-23 |
CN107825144B CN107825144B (en) | 2023-08-04 |
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CN201711259652.7A Active CN107825144B (en) | 2017-12-04 | 2017-12-04 | Numerical control perforating device for glass fiber reinforced plastic storage tank and tower |
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Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPH08132338A (en) * | 1994-11-08 | 1996-05-28 | Masakazu Miyashita | Device for machining outer periphery of stepped workpiece |
CN103170657A (en) * | 2011-12-23 | 2013-06-26 | 王布兴 | Numerical control lathe with automatic punching device |
CN104889745A (en) * | 2015-06-12 | 2015-09-09 | 来安县新元机电设备设计有限公司 | Machining all-in-one machine device |
CN105345079A (en) * | 2015-12-15 | 2016-02-24 | 天津市天森智能设备有限公司 | Digital control drilling machine for slope punching |
CN205685007U (en) * | 2016-06-03 | 2016-11-16 | 沈阳德文特动力机械制造有限公司 | Camshaft VVT machining of oil hole special plane |
-
2017
- 2017-12-04 CN CN201711259652.7A patent/CN107825144B/en active Active
Patent Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPH08132338A (en) * | 1994-11-08 | 1996-05-28 | Masakazu Miyashita | Device for machining outer periphery of stepped workpiece |
CN103170657A (en) * | 2011-12-23 | 2013-06-26 | 王布兴 | Numerical control lathe with automatic punching device |
CN104889745A (en) * | 2015-06-12 | 2015-09-09 | 来安县新元机电设备设计有限公司 | Machining all-in-one machine device |
CN105345079A (en) * | 2015-12-15 | 2016-02-24 | 天津市天森智能设备有限公司 | Digital control drilling machine for slope punching |
CN205685007U (en) * | 2016-06-03 | 2016-11-16 | 沈阳德文特动力机械制造有限公司 | Camshaft VVT machining of oil hole special plane |
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