CN106746522A - 3D glass forming methods - Google Patents

3D glass forming methods Download PDF

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Publication number
CN106746522A
CN106746522A CN201710076221.0A CN201710076221A CN106746522A CN 106746522 A CN106746522 A CN 106746522A CN 201710076221 A CN201710076221 A CN 201710076221A CN 106746522 A CN106746522 A CN 106746522A
Authority
CN
China
Prior art keywords
operating platform
mould
temperature
applicator
circle
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.)
Pending
Application number
CN201710076221.0A
Other languages
Chinese (zh)
Inventor
钟永材
熊智春
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Zhongshan Win Win Intelligent Equipment Co Ltd
Original Assignee
Zhongshan Win Win Intelligent Equipment Co Ltd
Priority date (The priority date 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 date listed.)
Filing date
Publication date
Application filed by Zhongshan Win Win Intelligent Equipment Co Ltd filed Critical Zhongshan Win Win Intelligent Equipment Co Ltd
Priority to CN201710076221.0A priority Critical patent/CN106746522A/en
Publication of CN106746522A publication Critical patent/CN106746522A/en
Pending legal-status Critical Current

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Classifications

    • CCHEMISTRY; METALLURGY
    • C03GLASS; MINERAL OR SLAG WOOL
    • C03BMANUFACTURE, SHAPING, OR SUPPLEMENTARY PROCESSES
    • C03B23/00Re-forming shaped glass
    • C03B23/02Re-forming glass sheets
    • C03B23/023Re-forming glass sheets by bending
    • C03B23/0235Re-forming glass sheets by bending involving applying local or additional heating, cooling or insulating means
    • YGENERAL 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
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02PCLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
    • Y02P40/00Technologies relating to the processing of minerals
    • Y02P40/50Glass production, e.g. reusing waste heat during processing or shaping
    • Y02P40/57Improving the yield, e-g- reduction of reject rates

Abstract

The invention discloses a kind of 3D glass forming methods.The 3D glass forming methods comprise the following steps:The drive cylinder drives first operating platform to move to the first specified location;The mould is heated to the first assigned temperature by the applicator circle in specifying the time first;The drive cylinder drives first operating platform to move to initial position;The mould is delivered to second operating platform by the allocation mechanism from first operating platform;The drive cylinder drives second operating platform to move to the second specified location;The mould is heated to the second assigned temperature by the applicator circle in specifying the time second;The drive cylinder drives the second operating platform edge to move to initial position away from the applicator circle direction;Close the applicator circle.The 3D glass forming methods that the present invention is provided solve the technical problem of processing inconvenience and low production efficiency in correlation technique.

Description

3D glass forming methods
Technical field
The present invention relates to glass processing field, and in particular to a kind of 3D glass forming methods.
Background technology
Existing sheet glass hot bending processing technology deforms Glass Transition to be formed by heating, its it is conventional plus Work sets and typically realizes its processing technology by mould and heating furnace R. concomitans, i.e., under heating furnace effect, sheet glass Can be softened according to mould and be shaped to specific dimensions or shape, but, due to the limitation of mould so that sheet glass heat The shape and size for curving picture are also restricted, if being to produce purpose with multi-specification glass, and need the shaping mould of many specifications Tool, so as to cause production cost to increase, therefore realizes that multi-specification glass sheetmolding is a problem for remaining unsolved.
Simultaneously again because heating furnace sets up scale and mode of operation, its be also high cost factor of production it One, it can be seen that, the realization of existing sheet glass hot bending processing sets up and its technique is to need larger its limitation of cost It is larger, and the sheet glass total output of hot bending is low, and the shaping of hot bending efficiency is low, is unfavorable for sheet glass hot bending technique Development.
Therefore, it is necessary to providing a kind of new 3D glass forming methods solves above-mentioned technical problem.
The content of the invention
In order to solve the above-mentioned technical problem, the present invention provides a kind of simple structure, heating effect is excellent and production efficiency is high 3D glass forming methods.
The present invention provides 3D glass forming methods, the 3D glass forming methods, for processing 3D thin sheet glass, including such as Lower step:
Offer stores mould, applicator circle, temperature sensor, first operation of the 3D thin sheet glass to be processed Platform and drive cylinder, wherein, the mould is located at first operating platform, and the temperature sensor is used to detect the mould The temperature of tool;
The drive cylinder drives first operating platform to move to the first finger along near the applicator circle direction Positioning is put;
The mould is heated to the first assigned temperature by the applicator circle in specifying the time first, wherein, first The scope of the time of specifying is 10 to 70 seconds, and the scope of first assigned temperature is 350 to 750 degrees Celsius;
When the temperature that the temperature sensor detects the mould reaches first assigned temperature, the driving gas Cylinder drives first operating platform to move to initial position along the direction away from the applicator circle;
Allocation mechanism and the second operating platform are provided;
When first operating platform moves to initial position, the allocation mechanism operates the mould from described first Platform is delivered to second operating platform;
The drive cylinder drives second operating platform to move to the second finger along near the applicator circle direction Positioning is put;
The mould is heated to the second assigned temperature by the applicator circle in specifying the time second, wherein, it is described The scope of the second specified time is 10 to 70 seconds, and the scope of second assigned temperature is 500 to 850 degrees Celsius;
When the temperature that the temperature sensor detects the mould reaches second assigned temperature, the driving gas Cylinder drives the second operating platform edge to move to initial position away from the applicator circle direction;
Close the applicator circle.
Preferably, the described first specified time was 30 seconds, and first assigned temperature is 400 degrees Celsius.
Preferably, the described second specified time was 35 seconds, and second assigned temperature is 550 degrees Celsius.
Preferably, the temperature sensor is infrared ray sensor.
Correlation technique is compared to, the 3D glass forming methods that the present invention is provided have following beneficial effect:
The 3D glass forming methods comprise the following steps:
The drive cylinder drives first operating platform to move to the first finger along near the applicator circle direction Positioning is put;
The mould is heated to the first assigned temperature by the applicator circle in specifying the time first, wherein, first The scope of the time of specifying is 10 to 70 seconds, and the scope of first assigned temperature is 350 to 750 degrees Celsius;
When the temperature that the temperature sensor detects the mould reaches first assigned temperature, the driving gas Cylinder drives first operating platform to move to initial position along the direction away from the applicator circle;
Allocation mechanism and the second operating platform are provided;
When first operating platform moves to initial position, the allocation mechanism operates the mould from described first Platform is delivered to second operating platform;
The drive cylinder drives second operating platform to move to the second finger along near the applicator circle direction Positioning is put;
The mould is heated to the second assigned temperature by the applicator circle in specifying the time second, wherein, it is described The scope of the second specified time is 10 to 70 seconds, and the scope of second assigned temperature is 500 to 850 degrees Celsius;
When the temperature that the temperature sensor detects the mould reaches second assigned temperature, the driving gas Cylinder drives the second operating platform edge to move to initial position away from the applicator circle direction;
Close the applicator circle.
Compared with correlation technique, the 3D glass forming methods of present invention offer are conducted heat by high-frequency heating and mould and realize adding Thermal effect is good, and speed is fast, heating function is improve, so that farthest with a constant temperature, overlap heating by once preheating Improve production efficiency.
Brief description of the drawings
Fig. 1 is for the structural representation of the 3D glass bending forming machines for providing 3D glass forming methods of the invention;
Fig. 2 is the front view of the 3D glass bending forming machines shown in Fig. 1;
The workflow diagram of the 3D glass forming methods that Fig. 3 is provided for the present invention.
Specific embodiment
The present invention will be further described with implementation method below in conjunction with the accompanying drawings.Fig. 1 and Fig. 2, Fig. 1 are please referred to for this The stereogram of the 3D glass bending forming machines for providing is invented, Fig. 2 is the front view of the 3D glass bending forming machines shown in Fig. 1.Institute 3D glass bendings forming machine 100 is stated, for processing 3D thin sheet glass, it includes stand 1, heating component 2, operating platform 3, driving Cylinder 4, connecting platform 5, mould 6, allocation mechanism 7 and temperature sensor 8.
The heating component 2 is suspended in the stand 1, and the heating component 2 includes applicator circle 21 and support 23, The applicator circle 21 includes the first applicator circle 211 and the second applicator circle 213, the first applicator circle 211 are disposed adjacent with the second applicator circle 213 interval, and the support 23 includes first support 231 and second support 233, the first support 231 connects the first applicator circle 211 and the stand 1, the connection of the second support 233 institute State the second applicator circle 213 and the stand 1.
The operating platform 3 is oppositely arranged, institute through the bottom of the stand 1 with the applicator circle 21 interval Stating operating platform 3 includes the first operating platform 31 and the second operating platform 33, first operating platform 31 and the described second behaviour Make the interval of platform 33 to be disposed adjacent, first operating platform 31 is oppositely arranged with the first applicator circle 211 interval, institute The second operating platform 33 is stated to be oppositely arranged with the second applicator circle 213 interval.
The drive cylinder 4 includes the first drive cylinder 41 and the second drive cylinder 43, and first drive cylinder 41 drives Move first operating platform 31 to be moved along the direction closer or far from the first applicator circle 211, described second drives Cylinder 43 drive second operating platform 33 along closer or far from the second applicator circle 213 along closer or far from described The direction motion of the second applicator circle 213.
Specifically, first operating platform 31 includes the first supporting plate 311 and the first guide pillar 313, first guide pillar 313 Through the bottom of the stand 1, and first supporting plate 311 and first drive cylinder 41 are connected, second operation is flat Platform 33 includes the second supporting plate 331 and the second guide pillar 333, and second guide pillar 333 is through the bottom of the stand 1, and connection institute The second supporting plate 331 is stated with second drive cylinder 43.
The connecting platform 5 connects first supporting plate 311 with second supporting plate 331.
The mould 6 is located at the first supporting plate 311 of first operating platform 31, for storing 3D thin slice glass to be processed Glass.
The allocation mechanism 7 is disposed adjacent with first supporting plate 311, for the institute by first supporting plate 311 is located at Mould 6 is stated to be delivered on second supporting plate 331 of second operating platform 33 through the connecting platform 5.
The temperature sensor 8 is fixedly arranged on the stand 1, the temperature sensor 8 include the first temperature sensor 81 and Second temperature sensor 83, first temperature sensor 81 is oppositely arranged with the first applicator circle 211 interval, and uses The temperature of the mould 6 of first operating platform 31, the second temperature sensor 83 and described second are located in detection The interval of applicator circle 213 is oppositely arranged, and for detecting the temperature of the mould 6 positioned at second operating platform 33. First temperature sensor 81 and the second temperature sensor 83 are infrared temperature sensor.
Refer to Fig. 3, the workflow diagram of the 3D glass forming methods that Fig. 3 is provided for the present invention, the 3D glass shaping Method comprises the following steps:
Offer stores mould 6, applicator circle 21, the temperature sensor 8, first of the 3D thin sheet glass to be processed Operating platform 31 and drive cylinder 4, wherein, the mould 6 is located at first operating platform 31, and the temperature sensor 8 is used In the temperature for detecting the mould 6;
The drive cylinder 4 drives first operating platform 31 to move to the along near the direction of applicator circle 21 One specified location;
Specifically, first drive cylinder 4 drives first operating platform 31 along near first applicator Enclose 211 directions and move to the first specified location;
The mould 6 is heated to the first assigned temperature by the applicator circle 21 in specifying the time first, wherein, the The scope of one specified time is 10 to 70 seconds, and the scope of first assigned temperature is 350 to 750 degrees Celsius;
Specifically, specify the first applicator circle 211 in the time that the mould 6 is heated into first first specifying Temperature;
When the temperature that the temperature sensor 8 detects the mould 6 reaches first assigned temperature, the driving Cylinder 4 drives first operating platform 31 to move to initial position along the direction away from the applicator circle 21;
Specifically, first drive cylinder 4 drives first operating platform 31 along away from first applicator The direction of circle 211 moves to initial position;
The operating platform 33 of allocation mechanism 7 and second is provided;
When first operating platform 31 moves to initial position, the allocation mechanism 7 is by the mould 6 from described first Operating platform 31 is delivered to second operating platform 33;
The drive cylinder 4 drives second operating platform 33 to move to the along near the direction of applicator circle 21 Two specified locations;
Specifically, second drive cylinder 43 drives second operating platform 33 along near second applicator Enclose 213 directions and move to the second specified location;
The mould 6 is heated to the second assigned temperature by the applicator circle 21 in specifying the time second, wherein, institute The scope for stating for the second specified time is 10 to 70 seconds, and the scope of second assigned temperature is 500 to 850 degrees Celsius;
Specifically, specify the second applicator circle 213 in the time that the mould 6 is heated into second second specifying Temperature;
When the temperature that the temperature sensor 8 detects the mould 6 reaches second assigned temperature, the driving Cylinder 4 drives second operating platform 33 to move to initial position along away from the direction of applicator circle 21;
Specifically, second drive cylinder 43 drives second operating platform 33 along away from second applicator Enclose 213 directions and move to initial position;
Close the applicator circle 21.
The first specified time was 30 seconds described in the present embodiment, and first assigned temperature is 400 degrees Celsius, described second The time of specifying is 35 seconds, and second assigned temperature is 550 degrees Celsius.
Correlation technique is compared to, the 3D glass forming methods that the present invention is provided have following beneficial effect:
The 3D glass forming methods, for processing 3D thin sheet glass, comprise the following steps:
Offer stores mould 6, applicator circle 21, the temperature sensor 8, first of the 3D thin sheet glass to be processed Operating platform 31 and drive cylinder 4, wherein, the mould 6 is located at first operating platform 31, and the temperature sensor 8 is used In the temperature for detecting the mould 6;
The drive cylinder 4 drives first operating platform 31 to move to the along near the direction of applicator circle 21 One specified location;
The mould 6 is heated to the first assigned temperature by the applicator circle 21 in specifying the time first, wherein, the The scope of one specified time is 10 to 70 seconds, and the scope of first assigned temperature is 350 to 750 degrees Celsius;
When the temperature that the temperature sensor 8 detects the mould 6 reaches first assigned temperature, the driving Cylinder 4 drives first operating platform 31 to move to initial position along the direction away from the applicator circle 21;
The operating platform 33 of allocation mechanism 7 and second is provided;
When first operating platform 31 moves to initial position, the allocation mechanism 7 is by the mould 6 from described first Operating platform 31 is delivered to second operating platform 33;
The drive cylinder 4 drives second operating platform 33 to move to the along near the direction of applicator circle 21 Two specified locations;
The mould 6 is heated to the second assigned temperature by the applicator circle 21 in specifying the time second, wherein, institute The scope for stating for the second specified time is 10 to 70 seconds, and the scope of second assigned temperature is 500 to 850 degrees Celsius;
When the temperature that the temperature sensor 8 detects the mould 6 reaches second assigned temperature, the driving Cylinder 4 drives second operating platform 33 to move to initial position along away from the direction of applicator circle 21;
Close the applicator circle 21.
Compared with correlation technique, the 3D glass forming methods that the present invention is provided are conducted heat with mould 6 by high-frequency heating and realized Heating effect is good, and speed is fast, heating function is improve, so that at utmost with a constant temperature, overlap heating by once preheating Improve production efficiency.
Embodiments of the invention are the foregoing is only, the scope of the claims of the invention is not thereby limited, it is every to utilize this hair Equivalent structure or equivalent flow conversion that bright specification and accompanying drawing content are made, or directly or indirectly it is used in other related skills Art field, is included within the scope of the present invention.

Claims (4)

1. a kind of 3D glass forming methods, for processing 3D thin sheet glass, its feature in,
Comprise the following steps:
Offer stores mould, applicator circle, temperature sensor, first operating platform of the 3D thin sheet glass to be processed And drive cylinder, wherein, the mould is located at first operating platform, and the temperature sensor is used to detect the mould Temperature;
The drive cylinder drives first operating platform to move to the first specific bit along near the applicator circle direction Put;
The mould is heated to the first assigned temperature by the applicator circle in specifying the time first, wherein, first specifies The scope of time is 10 to 70 seconds, and the scope of first assigned temperature is 350 to 750 degrees Celsius;
When the temperature that the temperature sensor detects the mould reaches first assigned temperature, the drive cylinder drives Dynamic first operating platform moves to initial position along the direction away from the applicator circle;
Allocation mechanism and the second operating platform are provided;
When first operating platform moves to initial position, the allocation mechanism is by the mould from first operating platform It is delivered to second operating platform;
The drive cylinder drives second operating platform to move to the second specific bit along near the applicator circle direction Put;
The mould is heated to the second assigned temperature by the applicator circle in specifying the time second, wherein, described second The scope of the time of specifying is 10 to 70 seconds, and the scope of second assigned temperature is 500 to 850 degrees Celsius;
When the temperature that the temperature sensor detects the mould reaches second assigned temperature, the drive cylinder drives The dynamic second operating platform edge moves to initial position away from the applicator circle direction;
Close the applicator circle.
2. 3D glass forming methods according to claim 1, it is characterised in that:Described first specified time was 10 to 70 Second, first assigned temperature is 350 to 750 degrees Celsius.
3. 3D glass forming methods according to claim 2, it is characterised in that:Described second specified time was 10 to 70 Second, second assigned temperature is 500 to 850 degrees Celsius.
4. 3D glass forming methods according to claim 1, it is characterised in that:The temperature sensor is infrared ray sensing Device.
CN201710076221.0A 2017-02-13 2017-02-13 3D glass forming methods Pending CN106746522A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN201710076221.0A CN106746522A (en) 2017-02-13 2017-02-13 3D glass forming methods

Applications Claiming Priority (3)

Application Number Priority Date Filing Date Title
CN201710076221.0A CN106746522A (en) 2017-02-13 2017-02-13 3D glass forming methods
PCT/CN2017/115788 WO2018145513A1 (en) 2017-02-13 2017-12-13 3d glass forming method
ZA2018/00134A ZA201800134B (en) 2017-02-13 2018-01-08 3d glass forming method

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Publication Number Publication Date
CN106746522A true CN106746522A (en) 2017-05-31

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Country Status (3)

Country Link
CN (1) CN106746522A (en)
WO (1) WO2018145513A1 (en)
ZA (1) ZA201800134B (en)

Cited By (1)

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WO2018145513A1 (en) * 2017-02-13 2018-08-16 中山市合赢智能装备有限公司 3d glass forming method

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ZA201800134B (en) 2019-01-30

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