CN207351353U - Low heat transfer hollow glass folds poor detection device - Google Patents
Low heat transfer hollow glass folds poor detection device Download PDFInfo
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- CN207351353U CN207351353U CN201721175224.1U CN201721175224U CN207351353U CN 207351353 U CN207351353 U CN 207351353U CN 201721175224 U CN201721175224 U CN 201721175224U CN 207351353 U CN207351353 U CN 207351353U
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- glass
- graduated scale
- heat transfer
- low heat
- detection device
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Abstract
The utility model belongs to glass manufacturing apparatus technical field, more particularly to a kind of low heat transfer hollow glass folds poor detection device, including horizontal graduated scale, vertical graduated scale and flexible connection axis, one end of the transverse direction graduated scale is connected with one end of the vertical graduated scale and forms the right angle angle α for carrying out folded difference detection to the edge of low heat transfer hollow glass, and the horizontal graduated scale offers with the junction of the vertical graduated scale and is flexibly connected hole, the axis that is flexibly connected coordinates through flexible connection interporal lacuna described in the flexible connection Kong Bingyu so that the transverse direction graduated scale and the vertical graduated scale can be along the length direction slips of the flexible connection axis.The low heat transfer hollow glass of the utility model, which folds poor detection device, has measurement accurate, the advantages of saving manpower, can greatly improve detection efficiency;And low heat transfer hollow glass folds that poor detection device overall structure is simply firm, and stability is strong.
Description
Technical field
The utility model belongs to glass manufacturing apparatus technical field, more particularly to a kind of low heat transfer hollow glass folds poor detection
Device.
Background technology
The method that traditional hollow glass folds difference measurements is usually manually to survey the every sheet glass size for forming hollow glass
Subtract each other after amount and draw folded difference data.This kind of traditional method is not only time-consuming and laborious, and is not easy to operate, measurement knot resultant error compared with
Greatly.Especially, folded poor testing requirements higher of the low heat transfer hollow glass in production, and still using this kind of traditional method then
It can not be guaranteed to the quality control of low heat transfer hollow glass.
Utility model content
The purpose of this utility model is to provide a kind of low heat transfer hollow glass to fold poor detection device, it is intended to solves existing skill
The technical problem that method in art is not easy to operate for the folded difference measurements of low heat transfer hollow glass and measurement error is big.
To achieve the above object, the technical solution adopted in the utility model is:A kind of low heat transfer hollow glass folds poor detection
Device, including horizontal graduated scale, vertical graduated scale and flexible connection axis, one end of the transverse direction graduated scale and the vertical scale
One end of ruler connects and forms the right angle angle α for carrying out folded difference detection to the edge of low heat transfer hollow glass, and the horizontal stroke
Offered to graduated scale with the junction of the vertical graduated scale and be flexibly connected hole, the flexible connection axis connects through the activity
Connect and interporal lacuna cooperation is flexibly connected described in Kong Bingyu so that the transverse direction graduated scale and the vertical graduated scale can be along the work
The length direction of dynamic connecting shaft slides.
Preferably, the horizontal graduated scale and the vertical graduated scale are steel plate graduated scale.
Preferably, the horizontal graduated scale and the vertical graduated scale are integrally formed and make.
Preferably, the low heat transfer hollow glass includes the first glass, the second glass and wall, and the wall is fixed
Between first glass and second glass, and two walls be arranged at intervals and with first glass and institute
State the second glass and enclose jointly and set to form spaced gas layer;First glass includes the first glass substrate and the first low-radiation film
Layer, the first Low emissivity film layer are covered in first glass substrate towards the side of the spaced gas layer, and described second
Glass includes the second glass substrate and the second Low emissivity layer, and the second Low emissivity film layer is covered in the second glass substrate back of the body
To the side of the spaced gas layer.
Preferably, first glass substrate and second glass substrate by least two pieces of glass substrates superpositions and
Into.
Preferably, the described first low-emission coated layer list silver LOW-E film layers, double-silver LOW-E film layer or three silver medal LOW-E films
Layer.
Preferably, the described second low-emission coated layer includes the Si that sequentially lamination is set3N4Film layer, the first SiO2Film layer,
Ito film layer and the 2nd SiO2Film layer, the Si3N4Film layer is covered in the side of second glass substrate.
Preferably, the Si3N4The thickness of film is 20nm~40nm, the first SiO2The thickness of film is 25nm~50nm,
The thickness of the ito film is 50nm~100nm, the 2nd SiO2The thickness of film is 30nm~60nm.
Preferably, the wall includes empty space bar and butyl rubber, and the opposite sides of the empty space bar passes through
The butyl rubber is Nian Jie with first glass and second glass respectively.
Preferably, the wall further includes structure glue, and the structure glue is filled in first glass and described second
Between glass and backwards to the position of the spaced gas layer.
The beneficial effects of the utility model:The low heat transfer hollow glass of the utility model folds poor detection device, in use, will
The top of low heat transfer hollow glass is connected on the inside of horizontal graduated scale, then will be connected to low heat transfer on the inside of vertical graduated scale
The sidepiece of hollow glass, so that the junction that low heat transfer hollow glass is connected to horizontal graduated scale and vertical graduated scale is formed
Right angle angle, then low heat transfer hollow glass can be directly read by the scale on horizontal graduated scale and vertical graduated scale
Folded difference data, and axis slides horizontal graduated scale and vertical graduated scale can be to low heat transfer hollow glass relative to being flexibly connected
The folded difference of diverse location checked that whole operation process is easily achieved, measurement is accurate, saves manpower, can greatly improve
Detection efficiency;And low heat transfer hollow glass folds that poor detection device overall structure is simply firm, and stability is strong.So pass through this reality
The low heat transfer hollow glass of poor detection device measurement is folded with new low heat transfer hollow glass can effectively keep away the hollow glass of low heat transfer
There is folded difference and flow in client's hand and the problem of not installing occur in glass, avoid the economic loss caused by problems.
Brief description of the drawings
, below will be to embodiment or the prior art in order to illustrate more clearly of the technical scheme in the embodiment of the utility model
Attached drawing is briefly described needed in description, it should be apparent that, drawings in the following description are only that this practicality is new
Some embodiments of type, for those of ordinary skill in the art, without having to pay creative labor, can be with
Other attached drawings are obtained according to these attached drawings.
Fig. 1 is the structure diagram that the low heat transfer hollow glass that the utility model embodiment provides folds poor detection device.
Fig. 2 is that the low heat transfer hollow glass that the utility model embodiment provides is folded in the low heat transfer measured by poor detection device
The structure diagram of empty glass.
Fig. 3 is that the low heat transfer hollow glass that the utility model embodiment provides is folded in the low heat transfer measured by poor detection device
The Section View of second glass of empty glass.
Wherein, each reference numeral in figure:
10-the first glass the 11-the first glass substrate the 12-the first Low emissivity film layer
20-wall, 21-intermediate parting strips, 22-butyl rubber
31-the second glass substrate of the glass of 23-structure glue 30-the second
32-the second Low emissivity film layer 40-spaced gas layer 100-low heat transfer hollow glass
200-transverse direction graduated scale 300-211-hollow hole of vertical graduated scale
321—Si3N4The SiO of film layer 322-the2Film layer 323-ito film layer
324-the two SiO2Film layer 400-flexible connection axis 500-flexible connection hole.
Embodiment
The embodiment of the utility model is described below in detail, the example of the embodiment is shown in the drawings, wherein from beginning
Same or similar element is represented to same or similar label eventually or there is same or like element.Below by ginseng
The embodiment for examining the description of attached drawing 1~3 is exemplary, it is intended to for explaining the utility model, and it is not intended that to this practicality
New limitation.
In the description of the utility model, it is to be understood that term " length ", " width ", " on ", " under ", " preceding ",
The orientation or position relationship of the instruction such as " rear ", "left", "right", " vertical ", " level ", " top ", " bottom " " interior ", " outer " are based on attached
Orientation or position relationship shown in figure, are for only for ease of and describe the utility model and simplify to describe, rather than instruction or hint
Signified device or element must have specific orientation, with specific azimuth configuration and operation, therefore it is not intended that to this
The limitation of utility model.
In addition, term " first ", " second " are only used for description purpose, and it is not intended that instruction or hint relative importance
Or the implicit quantity for indicating indicated technical characteristic.Thus, define " first ", the feature of " second " can be expressed or
Implicitly include one or more this feature.In the description of the utility model, " multiple " are meant that two or two
More than, unless otherwise specifically defined.
In the utility model, unless otherwise clearly defined and limited, term " installation ", " connected ", " connection ", " Gu
It is fixed " etc. term should be interpreted broadly, for example, it may be fixedly connected or be detachably connected, or integrally;Can be
Mechanically connect or be electrically connected;It can be directly connected, can also be indirectly connected by intermediary, can be two
The interaction relationship of connection or two elements inside element.For the ordinary skill in the art, can basis
Concrete condition understands concrete meaning of the above-mentioned term in the utility model.
As shown in Figure 1, a kind of low heat transfer hollow glass that the utility model embodiment provides folds poor detection device, including horizontal stroke
To graduated scale 200, vertical graduated scale 300 and axis 400 is flexibly connected, one end of the transverse direction graduated scale 200 and the vertical quarter
One end of degree ruler 300 connects and forms the right angle angle α for carrying out folded difference detection to the edge of low heat transfer hollow glass 100,
And the horizontal graduated scale 200 offers with the junction of the vertical graduated scale 300 and is flexibly connected hole 500, the activity is even
Spindle 400 is flexibly connected 500 clearance fit of hole so that the transverse direction graduated scale through the flexible connection hole 500 and with described
200 and the vertical graduated scale 300 can be slided along the length direction of the flexible connection axis 400.
Specifically, will laterally when the low heat transfer hollow glass provided using the utility model embodiment folds poor detection device
The inner side of graduated scale 200 is connected to the top of low heat transfer hollow glass 100, is then connected to the inner side of vertical graduated scale 300
The sidepiece of low heat transfer hollow glass 100, is carved so that low heat transfer hollow glass 100 is connected to horizontal graduated scale 200 with vertical
Spend the right angle angle that the junction of ruler 300 is formed, then pass through the scale on horizontal graduated scale 200 and vertical graduated scale 300
The folded difference data of low heat transfer hollow glass 100 can be directly read, and horizontal graduated scale is slided relative to axis 400 is flexibly connected
200 and vertical graduated scale 300 the folded difference of the diverse location of low heat transfer hollow glass 100 can be checked, whole operation mistake
Journey is easily achieved, and measurement is accurate, is saved manpower, can be greatly improved detection efficiency;And low heat transfer hollow glass folds poor detection
Device overall structure is simply firm, and stability is strong.Low heat transfer hollow glass so Jing Guo the utility model embodiment folds poor inspection
The low heat transfer hollow glass 100 of survey device measurement, which can effectively keep away low heat transfer hollow glass 100, to be had folded difference and flows to client's hand
In there is the problem of not installing, avoid the economic loss caused by problems.
In the present embodiment, the transverse direction graduated scale 200 and the vertical graduated scale 300 are steel plate graduated scale.Specifically,
Using the graduated scale of steel material manufacture as horizontal graduated scale 200 and vertical graduated scale 300, it so may insure that graduated scale is resistance to
With and be unlikely to deform, avoid because deformation and cause the scale on graduated scale not accurate, that is to say, that, it can be ensured that this practicality newly
The low heat transfer hollow glass that the embodiment of type provides folds poor detection device can reliably use all the time.
In the present embodiment, the transverse direction graduated scale 200 and the vertical graduated scale 300 are integrally formed and make.Specifically, one
Body formed manufacture may insure the uniformity of product and horizontal graduated scale 200 is connected with vertical graduated scale 300 can
By property, and production cost can also be reduced when producing product in enormous quantities.
Elaborate below to the low heat transfer hollow glass 100 of the utility model embodiment detection object, such as Fig. 2 institutes
Show, low heat transfer hollow glass 100 includes being arranged at the first glass 10 of outdoor, is arranged at indoor second glass 30 and wall
20, the wall 20 is fixed between first glass 10 and second glass 30, and between two walls 20
Enclose every setting and jointly to set to form spaced gas layer 40 with first glass 10 and second glass 30;First glass
10 include the first glass substrate 11 and the first Low emissivity film layer 12, and the first Low emissivity film layer 12 is covered in first glass
For substrate 11 towards on the side of the spaced gas layer 40, second glass 30 includes the second glass substrate 31 and the second low spoke
Film layer is penetrated, the second Low emissivity film layer 32 is covered in second glass substrate 31 backwards to the side of the spaced gas layer 40
On.Specifically, first Low emissivity film layer 12 is set and second towards the side of spaced gas layer 40 in the first glass substrate 11
Glass substrate 31 sets the second Low emissivity film layer 32 backwards to the side of spaced gas layer 40, and such structure design can utilize the
One Low emissivity film layer 12 and the second Low emissivity film layer 32 farthest increase the reflection to thermal energy, while utilize wall
20th, the first glass 10 and the second glass 30 enclose that to set the spaced gas layer 40 to be formed farthest infrared inside and outside air lock jointly
The transmission of thermal energy, the two functions complement each other so that the low heat transfer hollow glass 100 of the utility model obtain it is most excellent
Energy-efficient performance.Hot coefficient, it is anti-oxidant, can tempering hot bending, without membrane removal the advantages that, and simple in structure, cost reduction.
In the present embodiment, first glass substrate 11 and second glass substrate 31 are by least two pieces of glass substrates
It is formed by stacking.Specifically, the setting of the quantitative range of glass substrate is passed through so that the first glass substrate 11 and the second glass substrate
31 have different thickness and performance, to adapt to different application environments, can also avoid the wasting of resources, cost-effective.
In the present embodiment, the first Low emissivity film layer 12 is single silver LOW-E film layers, double-silver LOW-E film layer or three silver medals
LOW-E film layers.Specifically, the first Low emissivity film layer 12 is the offline vacuum magnetic control cathodic sputtering of widely applied utilization at present
Single silver LOW-E film layers, double-silver LOW-E film layer or the three silver medal LOW-E film layers of deposition technique production.Silver layer has the spy of Low emissivity
Property, low emissivity glass have visible ray higher transmissivity, there is very high reflectivity to infrared ray, have good thermal insulation
Energy.Different silver layers is set to construct so that low heat transfer hollow glass 100 has different performances, promotes the multifarious of product
Development.
In the present embodiment, as shown in figure 3, the second Low emissivity film layer, including the Si that sequentially lamination is set3N4Film, first
SiO2Film layer 322,323 and the 2nd SiO of ito film layer2Film layer 324, the Si3N4Film is covered in second glass substrate 31
On side.Specifically, the second Low emissivity film layer 32 is once to be superimposed upon glass using offline vacuum magnetic control cathode sputtering deposition technology
Laminated film on glass substrate, its composition that is sequentially overlapped on second glass substrate 31 is that first layer is Si3N4Film layer
321, the second layer is the first SiO2Film layer 322, third layer are ito film layer 323, and the 4th layer is the 2nd SiO2Film layer 324.By this
The setting of film layer structure and the mutual cooperation of compound insulating glass structure realize that printing opacity and heat transfer control, so as to increase plated film
The diversity of hollow glass product, improves the energy-saving of film-coated hollow glass product under existing process, structure, while makes life
Produce efficiency to improve, production cost reduces.
In the present embodiment, the Si3N4The thickness of film is 20nm~40nm, the first SiO2The thickness of film for 25nm~
50nm, the thickness of the ito film is 50nm~100nm, the 2nd SiO2The thickness of film is 30nm~60nm.Specifically,
Si3N4The thickness of film can be 20nm, 22nm, 24nm, 26nm, 28nm, 30nm, 32nm, 34nm, 36nm, 38nm, 40nm etc., the
One SiO2The thickness of film for 25nm, 27nm, 29nm, 31nm, 33nm, 35nm, 37nm, 39nm, 41nm, 43nm, 45nm, 47nm,
49nm, 50nm etc., the thickness of ito film is 50nm~55nm, 55nm~60nm, 60nm~65nm, 65nm~70nm, 70nm~
75nm, 75nm~80nm, 80nm~85nm, 85nm~90nm, 90nm~95nm, 95nm~100nm etc., the 2nd SiO2The thickness of film
Spend for 30nm, 33nm, 36nm, 39nm, 42nm, 45nm, 48nm, 51nm, 54nm, 57nm, 60nm etc..Pass through the thickness of each film layer
Setting, can ensure product be provided simultaneously with it is good can tempering hot bending function, while meet light transmittance more than 80%.It is preferred that
Ground, Si3N4The thickness of film is 25nm, 35nm, the first SiO2The thickness of film is 35nm, 45nm, the thickness of ito film is 60nm,
90nm, the 2nd SiO2The thickness of film is 45nm, 55nm.
In the present embodiment, the wall 20 includes intermediate parting strips 21 and butyl rubber 22, the intermediate parting strips 21 it is opposite
Both sides are be bonded with first glass 10 and second glass 30 respectively by the butyl rubber 22.Specifically, the first glass
It is bonded, is allowed in 11 He of the first glass substrate using butyl rubber 22 between substrate 11, intermediate parting strips 21, indoor glass substrate three
The spaced gas layer 40 of one layer of all round closure is formed among second glass substrate 31, and then is combined into a monoblock hollow glass.
In the present embodiment, the wall 20 further includes structure glue 23, and the structure glue 23 is filled in first glass
Between 10 and second glass 30 and backwards to the position of the spaced gas layer 40.Specifically, structure glue 23 is used to be bonded the
One glass 10, the second glass 30 and intermediate parting strips 21 so that the company between the first glass 10, the second glass 30 and intermediate parting strips 21
Connect more firm.
In the present embodiment, the intermediate parting strips 21 are aluminum strip, and the width of the intermediate parting strips 21 is 8mm~10mm.Tool
Body, intermediate parting strips 21 are aluminum strip, can strengthen the intensity of the marginal texture of low heat transfer hollow glass 100, while pass through difference
Aluminum strip width, the spaced gas layer 40 of different-thickness can be obtained so that low heat transfer hollow glass 100 has different heat-insulated
Effect and sound-proofing effect, meet the diversity of product.
In the present embodiment, the middle part of the intermediate parting strips 21 offers hollow hole 211.Specifically.Meeting structural strength
Requirement under, the structure of hollow hole 211 can reduce the dosage of material, reduce cost.
In the present embodiment, the spaced gas layer 40 is air layer or layer of inert.Specifically, air layer and indifferent gas
Body layer has a good heat insulation, spaced gas layer 40 can farthest inside and outside air lock infrared heat transmission, and
Low heat transfer hollow glass 100 is caused to reach most excellent energy-efficient performance with the first glass 10 and being used cooperatively for the second glass 30.
Include successively for the second Low emissivity film layer 32 of the low heat transfer hollow glass 100 in the utility model embodiment below
The Si of superposition3N4Film layer 321, the first SiO2Film layer 322, ito film layer 323, the 2nd SiO2The processing technology of film layer 324.The processing
In technique:Each film layer adds rotating cathode sputtering sedimentation, wherein Si in connection using intermediate frequency power supply3N4321 thickness of film layer is
20nm~40nm, such as 25nm, 35nm, power are 50kW~100kW, such as 70kW, 90kW, supply frequency for 30kHz~
50kHz, such as 35kHz, 45kHz.SiO2Thicknesses of layers is 25nm~50nm, such as 35nm, 45nm, power for 70kW~
150kW, such as 80kW, 120kW, supply frequency are 30kHz~50kHz, such as 35kHz, 45kHz.323 thickness of ito film layer is
50nm~100nm, such as 60nm, 90nm, power are 150kW~300kW, such as 180kW, 220kW, supply frequency 30kHz
~50kHz, such as 35kHz, 45kHz.SiO2Thicknesses of layers is 30nm~60nm, such as 45nm, 55nm, power for 90kW~
180kW, such as 100kW, 150kW, supply frequency are 30kHz~50kHz, such as 35kHz, 45kHz.The design energy of above film layer
Enough ensure product be provided simultaneously with it is good can tempering hot bending function, while meet light transmittance more than 80%.
The above is only the preferred embodiment of the utility model only, is not intended to limit the utility model, all at this
All any modification, equivalent and improvement made within the spirit and principle of utility model etc., should be included in the utility model
Protection domain within.
Claims (10)
1. a kind of low heat transfer hollow glass folds poor detection device, it is characterised in that:Including horizontal graduated scale, vertical graduated scale and work
Dynamic connecting shaft, one end of the transverse direction graduated scale are connected with one end of the vertical graduated scale and are formed for hollow to low heat transfer
The edge of glass carries out the right angle angle α of folded difference detection, and the junction of the horizontal graduated scale and the vertical graduated scale is opened
Equipped with being flexibly connected hole, the flexible connection axis through being flexibly connected interporal lacuna cooperation described in the flexibles connection Kong Bingyu so that
Obtaining the horizontal graduated scale and the vertical graduated scale can slide along the length direction of the flexible connection axis.
2. low heat transfer hollow glass according to claim 1 folds poor detection device, it is characterised in that:The transverse direction graduated scale
It is steel plate graduated scale with the vertical graduated scale.
3. low heat transfer hollow glass according to claim 1 folds poor detection device, it is characterised in that:The transverse direction graduated scale
It is integrally formed and makes with the vertical graduated scale.
4. poor detection device is folded according to claims 1 to 3 any one of them low heat transfer hollow glass, it is characterised in that:It is described
Low heat transfer hollow glass includes the first glass, the second glass and wall, and the wall is fixed on first glass and institute
Between stating the second glass, and two walls are arranged at intervals and enclose and set jointly with first glass and second glass
Form spaced gas layer;First glass includes the first glass substrate and the first Low emissivity film layer, first low-radiation film
Layer is covered in first glass substrate includes the second glass substrate towards the side of the spaced gas layer, second glass
With the second Low emissivity layer, the second Low emissivity film layer is covered in second glass substrate backwards to the side of the spaced gas layer
Face.
5. low heat transfer hollow glass according to claim 4 folds poor detection device, it is characterised in that:The first glass base
Plate and second glass substrate are formed by stacking by least two pieces of glass substrates.
6. low heat transfer hollow glass according to claim 4 folds poor detection device, it is characterised in that:First Low emissivity
Film plating layer list silver LOW-E film layers, double-silver LOW-E film layer or three silver medal LOW-E film layers.
7. low heat transfer hollow glass according to claim 4 folds poor detection device, it is characterised in that:Second Low emissivity
Film plating layer includes the Si that sequentially lamination is set3N4Film layer, the first SiO2Film layer, ito film layer and the 2nd SiO2Film layer, the Si3N4
Film layer is covered in the side of second glass substrate.
8. low heat transfer hollow glass according to claim 7 folds poor detection device, it is characterised in that:The Si3N4The thickness of film
Spend for 20nm~40nm, the first SiO2The thickness of film is 25nm~50nm, and the thickness of the ito film is 50nm~100nm,
2nd SiO2The thickness of film is 30nm~60nm.
9. low heat transfer hollow glass according to claim 4 folds poor detection device, it is characterised in that:The wall includes
Empty space bar and butyl rubber, the opposite sides of the empty space bar by the butyl rubber respectively with first glass and
The second glass bonding.
10. low heat transfer hollow glass according to claim 9 folds poor detection device, it is characterised in that:The wall is also
Including structure glue, the structure glue is filled between first glass and second glass and backwards to the spaced gas layer
Position.
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CN201721175224.1U CN207351353U (en) | 2017-09-13 | 2017-09-13 | Low heat transfer hollow glass folds poor detection device |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN108613609A (en) * | 2018-06-07 | 2018-10-02 | 武汉武耀安全玻璃股份有限公司 | A kind of folded poor instrument of laminated glass |
CN109186418A (en) * | 2018-08-20 | 2019-01-11 | 彩虹集团(邵阳)特种玻璃有限公司 | A kind of overflow formed glass cuts the measuring device and method of quality |
-
2017
- 2017-09-13 CN CN201721175224.1U patent/CN207351353U/en active Active
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN108613609A (en) * | 2018-06-07 | 2018-10-02 | 武汉武耀安全玻璃股份有限公司 | A kind of folded poor instrument of laminated glass |
CN109186418A (en) * | 2018-08-20 | 2019-01-11 | 彩虹集团(邵阳)特种玻璃有限公司 | A kind of overflow formed glass cuts the measuring device and method of quality |
CN109186418B (en) * | 2018-08-20 | 2021-11-05 | 彩虹集团(邵阳)特种玻璃有限公司 | Device and method for measuring cutting quality of overflow formed glass |
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