CN209242911U - Mould structure and process equipment applied to molding optical glass eyeglass - Google Patents
Mould structure and process equipment applied to molding optical glass eyeglass Download PDFInfo
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- CN209242911U CN209242911U CN201822085421.5U CN201822085421U CN209242911U CN 209242911 U CN209242911 U CN 209242911U CN 201822085421 U CN201822085421 U CN 201822085421U CN 209242911 U CN209242911 U CN 209242911U
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Abstract
The utility model relates to be applied to the mould structure and process equipment of molding optical glass eyeglass, mould structure includes the first mold and the second mold, and the first mold has column outer diameter face, the first end face that one end of the first mold has;Second mold has column aperture surface, and one end of the second mold has the second end face of certain surface shape corresponding with the end surface shape of the first mold;The column outer diameter face of first mold is placed in the column aperture surface of the second mold, and first end face and second end face are staggered relatively, formation cavitys;Cooperated using the column outer diameter face of the first mold and the column aperture surface of the second mold, the problem of making entire mould structure only exist unique face shape distortion and inclined fit clearance for influencing first end face and second end face, accumulating the amount of causing so as to improve dual distortion caused by two fit clearances present in known mould structure and/or the superposition of dual inclined greatly and produce glass lens substandard products.
Description
Technical field
The utility model relates to the mould structures of model eyeglass, are applied to model optics glass more specifically to one kind
The mould structure and process equipment of glass eyeglass.
Background technique
General optical articles all have an accurate optical mirror slip, optical mirror slip be roughly divided into spheric glass, aspherical lens,
Diffraction eyeglass, free surface lens, spheric glass is manufactured mostly with grinding method at present, and aspherical lens, diffraction eyeglass,
Free surface lens are then mostly manufactured with the technology of mould model.
It from the above, is usually all benefit when being manufactured using mould model method in the manufacturing technology of well known optical mirror slip
With pairs of mold shape forming cavity is cooperated, it is squeezed and deformed the glass material of softening at required shape
Shape, and required glass lens are obtained after the cooling period.Usually there is machining tolerance in this mold and mold and assembly is public when assembling
Difference, so that mold and mold are easy assembling and (or) disassembly.However, this machining tolerance be formed by gap be easy to cause mold in
The phenomenon that shifting and (or) tilt when assembling so that the glass lens produced there is two face shape distortions and
(or) inclination the problem of.
With development in science and technology, present optical articles are higher and higher to the image quality requirement of optical system, natural to light
The requirement for learning eyeglass is also increasingly harsher, such as mobile phone camera lens, mobile phone 3D structure light, on-vehicle lens, unmanned intelligence
Drive optical system, AR optical system etc.;These previous optical systems are to two face shape distortion amounts of optical mirror slip
It is required that be≤0.005mm, and present requirement is≤0.003mm even 0.0015mm;These previous optical systems are to optics
The requirement of two face shape inclined amounts of eyeglass is≤0.016 °, and present requirement be≤0.008 ° even
0.004°;It can no longer meet requirement using the glass lens that well known mould structure produces.
Fig. 1 is a kind of cross-sectional view of well known mould structure.Referring to FIG. 1, well known mould structure 100, this mold knot
Structure 100 includes being in the form of a column and mutual corresponding upper mold 110, lower mold 120 and cylindrical mould 190, one end of upper mold have
One end of the end face 114 of characteristic shape, lower mold has characteristic shape corresponding with upper mold end face end face 124, upper mold
110 and the column outer diameter face 112 and 122 of lower mold 120 be respectively placed in the column aperture surface 192 of cylindrical mould 190, and upper mold
Have end face 114 and lower die face 124 in cylindrical mould 190 it is opposite it, with shape forming cavity 1912.However, well known
Face bias situation during optical mirror slip model, caused by easily occurring because of mold fit clearance.
Fig. 2 and Fig. 3 is the upper mold central axis C11 and lower mold central axis C12 of well known mould structure 100 in tubular mould
Has the schematic diagram for the D1 that shifts in 190, this offset D1 is present in two offset ds 19 and the superposition accumulation of d29, and deviates D1 most
The case where can be equal to the sum of offset d 19 and offset d 29 greatly has certain probability.It please also refer to Fig. 2 Fig. 3.Firstly, such as Fig. 2
It is shown, upper mold 110, lower mold 120, glass material 15, cylindrical mould 190 are assembled.Due to the column of upper mold 110
All there are processing public affairs for the column aperture surface 192 of the column outer diameter face 122 and cylindrical mould 190 of outer diameter face 112 and lower mold 120
Difference, upper mold 110 and lower mold 120 can form gap 4910 and 4902 with cylindrical mould 190 respectively, at this time upper mold central axis
C11 relative to easily forming different degrees of offset d 19 between cylindrical mould central axis C19, lower mold central axis C12 relative to
Also different degrees of offset d 29 is easily formed between cylindrical mould central axis C19.Therefore, as shown in figure 3, when upper mold 110 with
When the pressing of lower mold 120 makes the molding (as shown in Figure 2) of glass material 15, face shape central axis that glass material 15 is contacted with upper mold
It is overlapped with the central axis C11 of upper mold, the central axis C12 of the face shape central axis that glass material 15 is contacted with lower mold and lower mold
It is overlapped, and is obtained after model there are the glass lens substandard products 15a of two sides shape distortion D1, and deviating D1 maximum can be with
There is certain probability equal to the case where the sum of offset d 19 and offset d 29.
Fig. 4 and Fig. 5 is the upper mold central axis C11 and lower mold central axis C12 of well known mould structure 100 in tubular mould
The schematic diagram of run-off the straight θ 1 in tool 190, this cant angle theta 1 is present in two cant angle thetas 19 and the superposition accumulation of θ 29, and cant angle theta 1 is most
The case where can be equal to the sum of cant angle theta 19 and cant angle theta 29 greatly has certain probability.It please refer to Fig. 4, above-mentioned 4910 He of gap
4902, in addition to be easy to causeing upper mold central axis C11 and the phenomenon that lower mold central axis C12 shifts, also be easy to cause upper mold
Has the phenomenon that central axis C11 and lower mold central axis 1 θ of C12 run-off the straight.Therefore, as shown in figure 5, working as upper mold 110 and lower die
When 120 pressing of tool makes the molding (as shown in Figure 4) of glass material 15, face shape central axis that glass material 15 is contacted with upper mold with it is upper
Mold center axis C11 is overlapped, and the face shape central axis that glass material 15b is contacted with lower mold is overlapped with lower mold central axis C12, and
It is obtained after model there are the glass lens substandard products 15b of two sides shape inclined θ 1, and 1 maximum of cant angle theta can be equal to and incline
, there is certain probability in the case where oblique the sum of θ 19 and cant angle theta 29.
Fig. 6 is a kind of cross-sectional view of well known mould structure.But such well known mould structure, in optical glass lens mould
It causes when type to be infeasible.It is former according to its patent introduction (publication number CN 1775702A, application number 200410091026.8)
Because as follows:
The material of expanding layer is polyimides, and the long-term use temperature of polyimides is -200~300 DEG C, short-period used
Temperature is 400~450 DEG C, and decomposition temperature is 500~600 DEG C;That is, can be lost quickly when temperature reaches 400 DEG C or more
Its original physical characteristic is gone, and when temperature reaches 500 DEG C, this material can be broken off quickly;And glass material carries out model
When molding, temperature is all at 450~700 DEG C.So expanding layer has been unable to maintain that its original physical characteristic even at this temperature
It is to be decomposed.
Referring to FIG. 6, well known mould structure 200, this mould structure 200 includes being in the form of a column and mutual corresponding upper mold
210, lower mold 220 and cylindrical mould 290, one end of upper mold have the end face 214 of specific shape, and one end of lower mold has
With the end face 224 of the specific shape of 214 relativity of upper mold opposite, expanding layer is coated in the cylindricality outer diameter face 212 of upper mold
240, expanding layer 250, the column outer diameter face 212 of upper mold 210 and lower mold 220 are coated in the cylindricality outer diameter face 222 of lower mold
And 222 be respectively placed in the column aperture surface 292 of cylindrical mould 290, and upper mold end face 214 and lower die face 224 are in cylinder
In shape mold 290 it is opposite it, with shape forming cavity 2912.However, during well known optical mirror slip model, expanding layer 240,
250 failures are decomposed, the face bias situation caused by easily occurring because of mold fit clearance.
Utility model content
The technical problem to be solved by the present invention is in view of the above drawbacks of the prior art, provide one kind and be applied to
The mould structure of molding optical glass eyeglass, in a manner of reducing fit clearance quantity, so as to improve the two sides shape of optical mirror slip
The problem of distortion and/or inclination.
The technical scheme adopted by the utility model to solve the technical problem is as follows:
Construct a kind of mould structure applied to molding optical glass eyeglass, including the first mold and the second mold, wherein
First mold has a column outer diameter face, and one end of first mold has a first end face of certain surface shape, and described the
The face shape central axis of one end face is process on the basis of the central axis of the column outer diameter face of first mold;Second mould
Tool has column aperture surface, and one end of second mold has certain surface shape corresponding with the first end face shape
The face shape central axis of second end face, the second end face is processed on the basis of the central axis of the column aperture surface of second mold
It forms;The column outer diameter face of first mold is placed in the column aperture surface of second mold, and the first end
Face and the second end face are staggered relatively, form cavity;The column of the column outer diameter face of first mold and second mold
The face shape central axis for uniquely influencing the first end face Yu the second end face of entire mould structure is constituted between shape aperture surface
Offset and inclined fit clearance.
Mould structure described in the utility model applied to molding optical glass eyeglass, wherein in first mold
Be provided between second mold for limit molding after optical glass lens outer peripheral surface shape stop collar.
Mould structure described in the utility model applied to molding optical glass eyeglass, wherein the stop collar includes
For in the cavity soften after glass material be in contact first side, close to the first end face first surface and
The second surface being in contact in molding with the second end face;
Wherein, the first surface is vertical with the first side connect, and the second surface and the first side are hung down
It is direct-connected to connect.
Mould structure described in the utility model applied to molding optical glass eyeglass, wherein the stop collar also wraps
Include the second side for the close contact that offsets with the column aperture surface of second mold.
Mould structure described in the utility model applied to molding optical glass eyeglass, wherein the second end face with
Between the column aperture surface by for limit molding after optical glass lens outer peripheral surface shape annular convex platform connect.
Mould structure described in the utility model applied to molding optical glass eyeglass, wherein the annular convex platform packet
Include the third surface close to first end face setting, the 4th surface that is in contact with the second end face and in the cavity
The medial surface that glass material after softening is in contact;Wherein, the third surface, the 4th surface respectively with the medial surface
Vertical connection.
Mould structure described in the utility model applied to molding optical glass eyeglass, wherein the annular convex platform with
Second mold or with the first mold integrated setting.
Mould structure described in the utility model applied to molding optical glass eyeglass, wherein first mold with
Be provided between second mold for limit molding after optical glass lens outer peripheral surface shape annular stop part;
First mold is provided with annular groove compatible with the annular stop part shape, in first mold
When with second mold clamping, the annular stop part is located in the annular groove.
Mould structure described in the utility model applied to molding optical glass eyeglass, wherein in first mold
On be provided with first annular groove, the end face of the first center pillar body of the first annular groove is arranged in the first end face
On;
Second annular groove is provided on second mold, the second end face is set to the second annular groove
On the end face of second center pillar body;
In first mold and second mold clamping, the annular stop part is set in first newel
The outside of shape body and the second center pillar body, and be located in the first annular groove, the interior table of the annular stop part
Face is mutually arranged close to the cavity.
The utility model additionally provides a kind of process equipment applied to molding optical glass eyeglass comprising above-mentioned
Mould structure.
The utility model has the beneficial effects that: utilizing the column outer diameter face of the first mold and the column internal diameter of the second mold
Face is cooperated, and entire mould structure is made to only exist unique face shape distortion for influencing first end face and second end face and incline
Oblique fit clearance, so as to improve distortion dual caused by two fit clearances present in known mould structure
And/or dual inclined is superimposed the problem of accumulating the amount of causing greatly and producing glass lens substandard products.
Detailed description of the invention
In order to illustrate the embodiment of the utility model or the technical proposal in the existing technology more clearly, below in conjunction with attached drawing
And the utility model is described in further detail for embodiment, the accompanying drawings in the following description is only that the part of the utility model is implemented
Example, for those of ordinary skill in the art, without creative efforts, can also obtain according to these attached drawings
Obtain other accompanying drawings:
Fig. 1 is the structure sectional view that a kind of well known mould structure is used for model eyeglass;
Fig. 2 is the distortion schematic diagram of well known mould structure;
Fig. 3 is the distortion schematic diagram of well known mould structure;
Fig. 4 is the inclined schematic diagram of well known mould structure;
Fig. 5 is the inclined schematic diagram of well known mould structure;
Fig. 6 is the cross-sectional view of mould structure well known to another kind;
Fig. 7 is the structure sectional view of the mould structure of the utility model embodiment one;
Fig. 8 is the distortion schematic diagram of the utility model embodiment one;
Fig. 9 is the distortion schematic diagram of the utility model embodiment one;
Figure 10 is the inclined schematic diagram of the utility model embodiment one;
Figure 11 is the inclined schematic diagram of the utility model embodiment one;
Figure 12 is two die opening state cross-sectional view of the utility model embodiment;
Figure 13 is that the utility model embodiment two molds state cross-sectional view;
Figure 14 is the utility model embodiment three-part pattern state cross-sectional view;
Figure 15 is that the utility model embodiment three molds state cross-sectional view;
Figure 16 is four die opening state cross-sectional view of the utility model embodiment;
Figure 17 is that the utility model embodiment four molds state cross-sectional view;
Figure 18 is five die opening state cross-sectional view of the utility model embodiment;
Figure 19 is that the utility model embodiment five molds state cross-sectional view.
Specific embodiment
It is practical below in conjunction with this in order to keep the objectives, technical solutions, and advantages of the embodiments of the present invention clearer
Technical solution in new embodiment carries out clear, complete description, it is clear that described embodiment is the portion of the utility model
Point embodiment, rather than whole embodiments.Based on the embodiments of the present invention, those of ordinary skill in the art are not being paid
Every other embodiment obtained, belongs to the protection scope of the utility model under the premise of creative work.
Embodiment one
A kind of mould structure applied to molding optical glass eyeglass, as illustrated in figures 7-11, while refering to fig. 1-6, including
First mold 310 and the second mold 320, the first mold 310 have column outer diameter face 312, and one end of the first mold 310 has spy
Determine the first end face 314 of face shape, the face shape central axis of the certain surface shape first end face 314 of the first mold 310 is with the first mould
It is process on the basis of the central axis C31 of the column outer diameter face 312 of tool 310;Second mold 320 has column aperture surface 322, the
One end of two molds 320 has certain surface shape corresponding with 314 shape of first end face of 310 certain surface shape of the first mold
Second end face 324, the face shape central axis of the second end face 324 of the certain surface shape of the second mold 320 is with the second mold 320
It is process on the basis of the central axis C32 of column aperture surface 322;The column outer diameter face of first mold 310 and the second mold 320
Unique influence first end face 314 of entire mould structure and the face shape central axis of second end face 324 are constituted between column aperture surface
Offset and inclined fit clearance.
Staggered relatively, the glass material by the second end face 324 of the first end face 314 of the first mold 310 and the second mold 320
15 are placed between the first end face 314 of the first mold 310 and the second end face 324 of the second mold 320, by the first mold 310
Column outer diameter face 312 is placed in the column aperture surface 322 of the second mold 320, forms cavity 3012;At this time the first mold 310 with
Unique influence between first end face and the face shape distortion and inclined cooperation of second end face is only existed between second mold 320
Gap 4012.As shown in figure 9, when the first mold 310 and the pressing of the second mold 320 make the molding (as shown in Figure 8) of glass material 15,
The face shape central axis that glass material 15 is contacted with the first mold 310 is overlapped with the central axis C31 of the first mold 310, glass material
The 15 face shape central axises contacted with the second mold 320 are overlapped with the central axis C32 of the second mold 320, and glass is obtained after model
There is offset D3 in the two sides shape central axis of glass eyeglass high-class product 15c.But distortion D3 at this time only by the first mold 310 with
Existing unique face shape distortion for influencing first end face 314 and second end face 324 and inclined between second mold 320
Caused by fit clearance 4012, and the distortion D1 in well known mould structure 100 is by two fit clearances 4910
And 4902 be superimposed accumulation and cause, so in the relatively well known mould structure 100 of the distortion D3 in the utility model
Mandrel offset D1 has obtained significantly reducing, to produce glass lens high-class product 15c.
As shown in Figure 10, the first end face 314 of the first mold 310 and the second end face 324 of the second mold 320 are put relatively
It sets, glass material 15 is placed between the first end face 314 of the first mold 310 and the second end face 324 of the second mold 320, by
The column outer diameter face 312 of one mold 310 is placed in the column aperture surface 322 of the second mold 320, forms cavity 3012;At this time
Unique face shape central axis for influencing first end face 314 and second end face 324 is only existed between one mold 310 and the second mold 320
Offset and inclined fit clearance 4012.As shown in figure 11, when the first mold 310 and the pressing of the second mold 320 make glass material
When 15 molding (as shown in Figure 10), in the face shape central axis and the first mold 310 that glass material 15 is contacted with the first mold 310
Mandrel C31 is overlapped, the central axis C32 weight for the face shape central axis and the second mold 320 that glass material 15 is contacted with the second mold 320
It closes, and obtains the two sides shape central axis of glass lens 15d after model there are cant angle thetas 3.But inclined θ 3 at this time only by
Existing unique face shape center for influencing first end face 314 and second end face 324 between first mold 310 and the second mold 320
Caused by axle offset and inclined fit clearance 4012, and the inclined θ 1 in well known mould structure 100 is by two
A fit clearance 4910 and 4902, which is superimposed accumulation, to be caused, so the relatively well known mold of the inclined θ 3 in the utility model
Inclined θ 1 in structure 100 has obtained significantly reducing, to produce glass lens high-class product 15d.
To sum up, because only only one fit clearance can cause between each mold in the mould structure of the utility model
The face shape distortion of two end faces and (or) inclination, there are two between cooperation between each mold in relatively well known mould structure
Gap also results in dual distortion and (or) inclination and is superimposed accumulation, the glass mirror after greatly reducing model
Offset and (or) inclined amount between the two sides shape central axis of piece, to produce glass lens high-class product.
Embodiment two
Such as Figure 12 and Figure 13, respectively one of mould structure of the utility model molds cross-sectional view after preceding and molding.
Another face type for the 314 face type of first end face being different from Fig. 7, Fig. 8 is shown.In figure 12 it can be seen that
Gas vent 323 is provided on two molds 320, gas vent 323 is connected with cavity 3012, convenient in the first mold 310 and second
During relative motion molding occurs for mold 320, the air in cavity 3012 is discharged, is conducive to the first mold 310 and second
The assembly and fractionation of mold 320.
Embodiment three
As shown in figure 14, it is provided between the first mold 310 and the second mold 320 for optical glass after restriction molding
The stop collar 400 of lens periphery face shape;Guarantee the column outer diameter face of the first mold 310 and the column of the second mold 320 simultaneously
Unique influence first end face of entire mould structure and the face shape distortion of second end face are constituted between aperture surface 322 and are inclined
Oblique fit clearance.When the first mold 310 and the second mold 320 mold, 15 periphery of glass material of 400 pairs of stop collar meltings
Face is limited, and limits its outer peripheral surface shape according to processing request, for example, stop collar 400 and the glass material 15 of the melting
The face that outer peripheral surface is in contact is plane, then may make that the glass lens outer peripheral surface finally processed is plane.
Further, as shown in Figure 14 and Figure 15, above-mentioned stop collar 400 include for in cavity soften after glass material
Expect the first surface that the first side being in contact, close first end face are arranged and be in contact in molding with second end face second
Surface.Wherein, first surface is vertical with first side connect, and second surface is vertical with first side to be connect, the shape of first side
Shape is set as the shape of glass lens outer peripheral surface needs according to machined parameters.
In the present embodiment, although there is also fit clearances between stop collar 400 and the second mold, the fit clearance is not
It will affect face shape distortion and the inclination of first end face 314 and second end face 324, therefore will not influence adding for glass lens
Work precision.Therefore, the present embodiment still ensures that entire mould structure only exists unique face for influencing first end face and second end face
Shape distortion and inclined fit clearance, guarantee the machining accuracy of glass lens.
Further, as shown in Figure 14 and Figure 15, above-mentioned stop collar 400 further includes the column internal diameter with the second mold 320
Face 322 offsets the second side of close contact, is can guarantee during the first mold 310 and the molding of the second mold 320 in this way, limit
Position ring 400 is fixed, it is ensured that the integrality of entire mould structure improves machining accuracy.
Example IV
As shown in Figure 16 and Figure 17, the second end face 324 in above-mentioned mould structure and between column aperture surface 322 by being used for
The annular convex platform 500 for limiting optical glass lens outer peripheral surface shape after forming connects, and the medial surface of annular convex platform 500 is close to cavity
3012 settings, to limit 15 outer peripheral surface of glass material of melting, the shape of the medial surface is limited according to processing request;Together
When can guarantee to constitute between the column outer diameter face 312 of the first mold 310 and the column aperture surface 322 of the second mold 320 it is entire
Unique influence first end face of mould structure and the face shape distortion of second end face and inclined fit clearance, can protect in this way
Demonstrate,prove the glass lens machining accuracy finally processed.
Specifically, as shown in Figure 16 and Figure 17, above-mentioned annular convex platform 500 includes the third being arranged close to first end face 314
Surface, the 4th surface being in contact with second end face 324 and the inside being in contact with the glass material after softening in cavity 3012
Face;Wherein, the third surface, the 4th surface of annular convex platform 500 are vertical with medial surface respectively connect.
Preferably, as shown in Figure 16 and Figure 17,320 integrated setting of above-mentioned annular convex platform 500 and the second mold, Huo Zheyu
First mold, 310 integrated setting improves machining accuracy to guarantee the integrality of entire mould structure.
Embodiment five
As shown in Figure 18 and Figure 19, it is provided with and is used between the first mold 310 and the second mold 320 of above-mentioned mould structure
The annular stop part 600 of optical glass lens outer peripheral surface shape after forming is limited, the first mold 310 is provided with and annular stop part
The compatible first annular groove 315 of 600 shapes, when the first mold 310 and the second mold 320 mold, annular stop part 600
In first annular groove 315.
Specifically, first annular groove 315 is provided on the first mold 310, first end face 314 is arranged in first ring
On the end face of first center pillar body 3151 of connected in star 315.Second annular groove 325 is provided on the second mold 320, the
Biend 324 is set on the end face of the second center pillar body 3252 of the second annular groove 325.The first mold 310 with
When second mold 320 molds, above-mentioned annular stop part 600 is set in the first center pillar body 3151 and the second center pillar body
3252 outside, and be located in first annular groove 315.The inner surface of annular stop part 600 is arranged close to 3012 phase of cavity,
For limiting the glass lens outer peripheral surface shape finally processed according to processing request.
In the present embodiment, although between annular stop part 600 and the second mold 320 and between first end face 314
There are fit clearances, but the fit clearance will not influence the face shape distortion of first end face 314 and second end face 324 and incline
Tiltedly, therefore it will not influence the machining accuracies of glass lens.Therefore, the present embodiment still ensures that entire mould structure only exists uniquely
The face shape distortion and inclined fit clearance of influence first end face 314 and second end face 324 guarantee adding for glass lens
Work precision.
In another embodiment of the utility model, a kind of process equipment applied to molding optical glass eyeglass is provided,
The process equipment includes above-mentioned mould structure, and specific structure is referring to the description of embodiments above, and details are not described herein.
It should be understood that for those of ordinary skills, it can be modified or changed according to the above description,
And all these modifications and variations all should belong to the protection scope of the appended claims for the utility model.
Claims (10)
1. a kind of mould structure applied to molding optical glass eyeglass, including the first mold and the second mold, which is characterized in that
First mold has a column outer diameter face, and one end of first mold has a first end face of certain surface shape, and described the
The face shape central axis of one end face is process on the basis of the central axis of the column outer diameter face of first mold;Second mould
Tool has column aperture surface, and one end of second mold has certain surface shape corresponding with the first end face shape
The face shape central axis of second end face, the second end face is processed on the basis of the central axis of the column aperture surface of second mold
It forms;The column outer diameter face of first mold is placed in the column aperture surface of second mold, and the first end
Face and the second end face are staggered relatively, form cavity;The column of the column outer diameter face of first mold and second mold
The face shape central axis for uniquely influencing the first end face Yu the second end face of entire mould structure is constituted between shape aperture surface
Offset and inclined fit clearance.
2. the mould structure according to claim 1 applied to molding optical glass eyeglass, which is characterized in that described
Be provided between one mold and second mold for limit molding after optical glass lens outer peripheral surface shape stop collar.
3. the mould structure according to claim 2 applied to molding optical glass eyeglass, which is characterized in that the limit
Ring include for in the cavity soften after glass material be in contact first side, close to the first end face first
Surface and the second surface being in contact in molding with the second end face;
Wherein, the first surface is vertical with the first side connect, and the second surface is vertical with the first side to be connected
It connects.
4. the mould structure according to claim 3 applied to molding optical glass eyeglass, which is characterized in that the limit
Ring further includes the second side of close contact of offseting with the column aperture surface of second mold.
5. the mould structure according to claim 1 applied to molding optical glass eyeglass, which is characterized in that described second
Between end face and the column aperture surface by for limit molding after optical glass lens outer peripheral surface shape annular convex platform connect.
6. the mould structure according to claim 5 applied to molding optical glass eyeglass, which is characterized in that the annular
Boss include the third surface close to first end face setting, the 4th surface that is in contact with the second end face and with it is described
The medial surface that glass material in cavity after softening is in contact;Wherein, the third surface, the 4th surface respectively with it is described
Medial surface vertically connects.
7. the mould structure according to claim 5 applied to molding optical glass eyeglass, which is characterized in that the annular
Boss and second mold or with the first mold integrated setting.
8. the mould structure according to claim 1 applied to molding optical glass eyeglass, which is characterized in that described first
Be provided between mold and second mold for limit molding after optical glass lens outer peripheral surface shape annular stop part;
First mold is provided with annular groove compatible with the annular stop part shape, in first mold and institute
When stating the second mold clamping, the annular stop part is located in the annular groove.
9. the mould structure according to claim 8 applied to molding optical glass eyeglass, which is characterized in that described
First annular groove is provided on one mold, the first center pillar body of the first annular groove is arranged in the first end face
End face on;
Second annular groove is provided on second mold, the second end face is set to the second of the second annular groove
On the end face of center pillar body;
In first mold and second mold clamping, the annular stop part is set in the first center pillar body
With the outside of the second center pillar body, and be located at the first annular groove in, the inner surface of the annular stop part with
The cavity is mutually arranged close to.
10. a kind of process equipment applied to molding optical glass eyeglass, which is characterized in that comprising as appointed in claim 1-9
Mould structure described in one.
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