CN101659012B - Method for processing container glass mold - Google Patents

Abstract

The invention relates to a method for processing a mold, in particular to a method for processing a container glass mold. The method comprises the following steps: A. pouring a mold blank; B. fixing the mold blank on a numerical control (NC) machine tool and determining the uniform mold blank processing benchmark; and C. processing each side of the mold blank. By determining the uniform mold blank processing benchmark, the method can realize high uniformity of shape and position dimensions and linear dimension of the product and strongly ensure the product quality, thus increasing the qualified rate of the product and lowering the production cost. In addition, after uniforming the mold blank processing benchmark, rotary processing of each side of the mold blank greatly simplifies the production technology, thus achieving the effect of saving labor and time.

Description

A kind of processing method of container glass mold

Technical field

The present invention relates to the processing method of mould, especially a kind of processing method of container glass mold.

Background technology

The processing method of current container glass mold, operation is loaded down with trivial details, and production line is long, in production process, each face of die blank is processed separately, need to use multiple processing machine instead, and benchmark constantly converts, thereby can not guarantee morpheme size, cause product rejection rate high, production cost is high; In addition owing to not stipulating in process that in unified benchmark, process, randomness is large especially, especially in Milling Process link, because of no standard benchmark or be difficult to find benchmark, therefore generally can only adopt outer round arris edge during tool setting, cause error large, cause thus interchangeability can not be guaranteed.

Summary of the invention

Problem to be solved by this invention is: the processing method that a kind of container glass mold is provided, the method has been determined unified die blank machining benchmark, can make product morpheme size and linear dimension realize high unity, make product quality obtain strong guarantee, thereby improved product qualified rate, reduced production cost, and after unified die blank machining benchmark, each face of revolution processing mold blank, simplifies production technology greatly, reaches saving of labor, saves time, labour-saving effect.

The object of the present invention is achieved like this: a kind of processing method of container glass mold, comprises A casting die blank; Further comprising the steps of:

B is fixed on die blank on Digit Control Machine Tool, determines unified die blank machining benchmark;

Described unified die blank machining benchmark comprises datum plane, and processing revolution benchmark is bored in milling, Vehicle Processing center of circle benchmark, and datum plane produces by milling die blank one end end face; Milling is bored processing revolution benchmark and is produced by generating process hole on die blank two end end faces; Vehicle Processing center of circle benchmark produces by circular interpolation milling or cover boring die blank one end cylindrical;

By datum plane and milling, bore processing revolution benchmark and determine milling brill processing revolution axial line, by datum plane and Vehicle Processing center of circle benchmark, determine Vehicle Processing revolution axial line, described milling is bored processing revolution axial line and is parallel to each other or overlaps with Vehicle Processing revolution axial line, both are all perpendicular to described datum plane, and and the vertical center line of described datum plane intersect;

Each face of C processing mold blank.

Vehicle Processing center of circle benchmark produces by circular interpolation milling or the large end cylindrical of cover boring die blank.

Described datum plane produces by the large end end face 10 of milling die blank, on large end end face 10, generate the first fabrication hole 31, the second fabrication hole 32, the first fabrication hole 31 is positioned on the vertical center line of large end end face 10, angle >=45 of the second fabrication hole 32 and described large end end face vertical center line ° and≤75 °, on die blank small end end face 11, generate the 3rd center of circle for fabrication hole 33, the three fabrication holes 33 and the center of circle of the first fabrication hole 31 coaxial.

The first fabrication hole 31 equates with the distance of the second fabrication hole 32 to large end end face 10 centers of circle.

Described datum plane produces by the large end end face 10 of milling die blank, on large end end face 10, generate two the 4th fabrication holes 34,35, angle >=45 of the 4th fabrication hole 34,35 and described large end end face vertical center line ° and≤75 °, on die blank small end end face 11, generate two the 6th fabrication holes 36,37, the center of circle of the 6th fabrication hole 36 is coaxial with the center of circle of the 4th fabrication hole 34, and the center of circle of the 7th fabrication hole 37 is coaxial with the center of circle of the 5th fabrication hole 35.

The 4th fabrication hole 34 is with the 5th fabrication hole 35 to holding greatly the distance in end face 10 centers of circle to equate, the 4th fabrication hole (34) is being held on the same circle center line of end face greatly with the 5th fabrication hole (35).

Step C comprises: Vehicle Processing die blank inside and outside circle, inner chamber and end face, boring and milling bores revolution processing mold blank inside and outside circle, inner chamber and end face.

The invention has the advantages that:

1 owing to having given full play to the advantage of Digit Control Machine Tool and having determined unified die blank machining benchmark, can realize product size high unity, make product quality obtain strong guarantee, thereby make mould obtain the interchangeability of height, make glass mold produce more specialized simultaneously;

In 2 productions, fixture kind used obviously reduces, and special fixture is fully used, and has greatly reduced the input cost of producing;

Therefore 3 owing to having used special fixture, reduced the clamping time, turnaround time and the handling time of workpiece, reduced labour intensity; And on special fixture, can process two dies simultaneously and also can process in pairs and can not process in pairs and so greatly shorten process time and cycle, obviously improved production efficiency;

4 new technologies are short and sweet, for production management provides advantage;

5 owing to having simplified work flow, therefore reduced kind and the quantity of process equipment, reduced operating post, reaches saving of labor, timesaving effect.

Accompanying drawing explanation

Fig. 1 for the cold hole of hanging down be that circumference equal dividing distributes and wherein the cold hole of hanging down look schematic diagram in the right side of die blank while being positioned on the vertical center line of the large end end face of die blank;

Fig. 2 for the cold hole of hanging down be that circumference equal dividing distributes and wherein one hang down cold hole while being positioned on the vertical center line of the large end end face of die blank the master of die blank look schematic diagram;

Fig. 3 for the cold hole of hanging down be that circumference equal dividing distributes and wherein the cold hole of hanging down look schematic diagram in a left side for die blank while being positioned on the vertical center line of the large end end face of die blank;

Fig. 4 for the cold hole of hanging down be that circumference equal dividing distributes and when none cold hole of hanging down is positioned on the vertical center line of the large end end face of die blank the right side of die blank look schematic diagram;

Fig. 5 for the cold hole of hanging down be that circumference equal dividing distributes and when none cold hole of hanging down is positioned on the vertical center line of the large end end face of die blank the master of die blank look schematic diagram;

Fig. 6 for the cold hole of hanging down be that circumference equal dividing distributes and when none cold hole of hanging down is positioned on the vertical center line of the large end end face of die blank a left side for die blank look schematic diagram;

Fig. 7 is that circumference equal dividing distributes and cold hole two punch clamping machining state front views while being positioned on the vertical center line of the large end end face of die blank that hang down wherein for the cold hole of hanging down;

Fig. 8 is that circumference equal dividing distributes and cold hole two punch clamping machining state top views while being positioned on the vertical center line of the large end end face of die blank that hang down wherein for the cold hole of hanging down;

Fig. 9 is that circumference equal dividing distributes and the cold hole numerical control scale-division head end clamping position location schematic diagram while being positioned on the vertical center line of the large end end face of die blank that hangs down wherein for the cold hole of hanging down;

Figure 10 is that circumference equal dividing distributes and two punch clamping machining state front views when none cold hole of hanging down is positioned on the vertical center line of the large end end face of die blank for the cold hole of hanging down;

Figure 11 is that circumference equal dividing distributes and two punch clamping machining state top views when none cold hole of hanging down is positioned on the vertical center line of the large end end face of die blank for the cold hole of hanging down;

Figure 12 is that circumference equal dividing distributes and numerical control scale-division head end clamping position location schematic diagram when none cold hole of hanging down is positioned on the vertical center line of the large end end face of die blank for the cold hole of hanging down;

Figure 13 is the assembling front view that BLM-GZ-TYX01-00 bores milling two end fixtures;

Figure 14 is the assembling plan view that BLM-GZ-TYX01-00 bores milling two end fixtures;

Figure 15 is the partial left side view that BLM-GZ-TYX01-00 bores the assembling plan view of milling two end fixtures;

Figure 16 is the A-A-A cutaway view that BLM-GZ-TYX01-00 bores the assembling plan view of milling two end fixtures;

Figure 17 be BLM-GZ-TYX01-00 bore milling two end fixtures assembling plan view at the A-A-A cutaway view using in pressing plate refill-unit situation;

Figure 18 is the B-B cutaway view that BLM-GZ-TYX01-00 bores the assembling plan view of milling two end fixtures;

Figure 19 is the assembling front view of BLM-GZ-TYX02-00S (double end dividing head) two four sides, top rotary jigs;

Figure 20 is the A-A cutaway view of the assembling front view of BLM-GZ-TYX02-00S (double end dividing head) two four sides, top rotary jigs;

Figure 21 is the B-B cutaway view of the assembling front view of BLM-GZ-TYX02-00S (double end dividing head) two four sides, top rotary jigs;

Figure 22 is the C-C cutaway view of the assembling front view of BLM-GZ-TYX02-00S (double end dividing head) two four sides, top rotary jigs;

Figure 23 is that the assembling partial left of BLM-GZ-TYX02-00S (double end dividing head) two four sides, top rotary jigs is looked cutaway view;

Figure 24 is the D-D cutaway view of the assembling front view of BLM-GZ-TYX02-00S (double end dividing head) two four sides, top rotary jigs.

In figure: 1 Vehicle Processing center of circle benchmark, 2 datum planes, processing revolution benchmark is bored in 3 millings, 4 location-plates, 5 lathe table tops, 6 location compound plates, the large end end face of 10 die blank, 11 die blank small end end faces, 31 first fabrication holes, 32 second fabrication holes, 33 the 3rd fabrication holes, 34 the 4th fabrication holes, 35 the 5th fabrication holes, 36 the 6th fabrication holes, 37 the 7th fabrication holes, 38 location via holes, 39 centre of gyration points, 40 NC dividing heads, 51 right locating pins, 52 right corner degree locating pins, 54 compound plate locators, 55T type groove nut, 56 hexagon socket cap head screws, 57 magnet rings are responded to slim hydraulic cylinder, 58 magnet rings are responded to slim hydraulic cylinder, 60 bearing blocks, 62T type groove nut, 63 hexagon socket cap head screws, 64 hexagon socket cap head screws, 65 screw mandrels, 67 base plates, 68 bearing block cover plates, 69 dividing head keels, 70 positioning keys, 71 left locating pins, 72 tops, 73 sliding axles, 74 hydraulic cylinder piston knock-off joints, 76 screw rodb bases, 77 screws, 78 positioning keys, 79 steel bushings, 80 transformation of the way soket head cap screws, 81 brake block, 82FK15140X2 Double end digital control dividing head, 91 datum plates, 92 pressing plate guide pads, 93 pressing plate guide pad cover plates, 94 pressing plates, 95 right gusset pieces, 96 right gusset piece alignment pin, 97 Left-wing Federation's fishplate bars, 98 gyroaxises, 99 bearing blocks, 100 angle orientation pins, 101 bearing block cover plates, 102 base plates, 103 dividing head keels, 104 arm-ties, 105 pull bars, 1062-M8T type nut, 107 planar top stromas, 108 limited block A, 109 spacing blocks, 110 limited block cross bars, 111 pressing plate refill-units, 112 positioning keys, 113 positioning keys, 114T type groove nut, 115 hexagon socket cap head screws, 116 magnet rings are responded to slim hydraulic cylinder, 117 magnet rings are responded to slim hydraulic cylinder, 118FK15150B NC dividing head, 119 hexagon socket cap head screws, 120 hex nuts, 121 interior hexagonal flush end holding screws, 122 interior hexagonal flush end holding screws, 123 hexagon socket cap head screws, 124 hexagon socket cap head screws, 125 hexagon socket cap head screws, 126 hexagon socket cap head screws, 130 supportings, 131 fixture centre of gyration lines, 132 die blanks.

The specific embodiment

Below in conjunction with the drawings and specific embodiments, the invention will be further described.

The concrete operation of the embodiment of the present invention one is as follows:

1, according to customer requirement and glass mold technical specification, go out product figure;

2, by product figure requirement, decomposing, and propose the production early-stage preparations such as rational processing technology and required fixture, cutter, measurer, programming, is exactly here to adopt the present invention to carry out processing mold;

3, casting die blank, carries out proportioning casting by pattern and company standard, and annealing in process;

The equipment using is casting a complete set of equipment, and frock clamp is moulding wooden model, after producing, will test, and check emphasis is constituent analysis and the inspection of outward appearance casting flaw; Use measurer is spectroanalysis instrument, range estimation; Inspection frequency is 1/batch of spectrum analysis, and range estimation is inspection entirely.

4, die blank is fixed on Digit Control Machine Tool, determines unified die blank machining benchmark;

The vertical boring-milling center of Digit Control Machine Tool that the model that the equipment using is produced for Taiwan Fu Yu lathe limited company is 3060VMC, the frock clamp of use is BLM-GZ-TYX01-00 brill milling two end fixtures.

Described unified die blank machining benchmark comprises Vehicle Processing center of circle benchmark, datum plane, processing revolution benchmark is bored in milling, and more than determining, three benchmark are realized by boring-milling center first manufacturing procedure, in processing, with these three benchmark, carry out processing mold from start to finish, can not be destroyed.

The generation of three benchmark does not have sequence requirement, but by professional etiquette, is generally first to do datum plane, then does milling and bores processing revolution benchmark, finally does Vehicle Processing center of circle benchmark.

Datum plane 2 is generally to produce by the large end end face of milling die blank, under particular case, also can produce by milling die blank small end end face, such as the shorter situation in the face of cylinder of the large end cylindrical of die blank, be to produce datum plane 2 by the large end end face of milling die blank in the present embodiment; Milling is bored processing revolution benchmark 3 and is produced by generating process hole on die blank two end end faces; Vehicle Processing center of circle benchmark 1 produces by circular interpolation milling or the large end cylindrical of cover boring die blank, is exactly the center of circle of datum plane 2.

By datum plane 2 and milling, bore processing revolution benchmark 3 and determine milling and bore processing revolution axial line, milling is bored processing revolution axial line and is by milling and bores that benchmark 3 is turned round in processing and perpendicular to the straight line of datum plane 2.By datum plane 2 and Vehicle Processing center of circle benchmark 1, determine Vehicle Processing revolution axial line, Vehicle Processing revolution axial line is by Vehicle Processing center of circle benchmark 1 and perpendicular to the straight line of datum plane 2.Milling is bored processing revolution axial line and is turned round the correlation between axial line with Vehicle Processing: be parallel to each other or overlap, all perpendicular to datum plane 2, and and datum plane 2 vertical center line intersect, that is to say that with respect to Vehicle Processing revolution axial line translation certain distance (>=0) on the vertical center line of datum plane 2, just having produced milling bores processing revolution axial line.The small-sized die blank of general processing can make Vehicle Processing revolution axial line and milling brill processing revolution axial line overlap, the die blank of machining large, it is exactly the relation being parallel to each other that Vehicle Processing revolution axial line and milling are bored between processing revolution axial line, in the present embodiment, it is exactly the relation being parallel to each other that Vehicle Processing revolution axial line and milling are bored between processing revolution axial line.

As Fig. 1, Fig. 2, shown in Fig. 3, on the large end end face 10 of die blank, process the first fabrication hole 31 and the second fabrication hole 32, the first fabrication hole 31 is positioned on the vertical center line of large end end face 10, processing revolution benchmark 3 is bored in the namely milling of the center of circle of the first fabrication hole 31, the angle of the second fabrication hole 32 and the vertical center line of large end end face 10 should >=45 ° and≤75 °, here, be decided to be 60 °, because 60 is 10, 12, 15 multiple, in processing, we wish to try one's best and do fabrication hole by vertical cold hole, vertical cold hole on general die blank is by circle distribution and alternate 10 to 12.5 degree, as long as do not produce interference with other places, the maximum probability that has the cold hole of hanging down on the position of 60 °, so 60 ° is best angle, can certainly select 45 °, 48 °, 50 °, 52 °, 55 °, 62 °, 65 °, 68 °, 70 °, 72, 75 ° of equal angles, only need in processing technology hole, relevant position.The first fabrication hole 31 and the second fabrication hole 32 can equate to the distance in large end end face 10 centers of circle also can be unequal, if unequal, need to make the location-plate of dimension, if equated, just can determine the location-plate of individual standard specification, to reuse.For the ease of production, energy-conservation, in the present embodiment, the first fabrication hole 31 equates with the distance of the second fabrication hole 32 to large end end face 10 centers of circle.On die blank small end end face 11, process the 3rd fabrication hole 33, the center of circle of the center of circle of the 3rd fabrication hole 33 and the first fabrication hole 31 is coaxial, by datum plane 2 and milling, bore processing revolution benchmark 3 and determine milling brill processing revolution axial line, the namely circle center line connecting of the first fabrication hole 31 and the 3rd fabrication hole 33.The second fabrication hole 32 is for angle orientation and play gearing.

On die blank, generally all needing the vertical cold hole of processing, in production, for position, number, the center-diameter in the vertical cold hole on die blank, do not do unified regulation, is generally by circle distribution and alternate 10 to 12.5 degree, as long as do not produce interference with other places.Although the actual conditions in mould manufacturing enterprise are so at present, for convenient, realize standardized production, we wish to try one's best and do fabrication hole by vertical cold hole, and the cold Kongzui that hangs down thus carries out well standardized designs.Fabrication hole is of a size of the present embodiment is exactly on the position of the first fabrication hole 31, the second fabrication hole 32,33, to have the satisfactory cold hole of hanging down, and now just can do fabrication hole by vertical cold hole, if do not had, processing technology hole is just passable.

Concrete operations are as follows: the die joint (also claiming joint close face in industry) of die blank of take is clamping datum plane, with three supporting-point location, then the compression mould blank face of cylinder, milling die blank two ends end face, on some punch die blank two end end faces, each hole comprises for determining the hole that needs on the vertical cold hole of benchmark and product design figure etc., the processing of brill milling hinge is used for the vertical cold hole of definite benchmark etc., overlaps the large end cylindrical of boring die blank, milling homalocephalus.

5, rough mill: take the first fabrication hole 31, the second fabrication hole 32, the 3rd fabrication hole 33 is clamping benchmark, and compression mould blank two end end faces, rough mill Hough face, lower interface, joint close interface on surfacing;

The equipment using is the vertical boring-milling center of 3060VMC Digit Control Machine Tool, and the frock clamp of use is BLM-GZ-TYX02-00 bis-four sides, top rotary jigs.

6, surfacing: preheated mold blank to 800～850 ℃, by surfacing figure requirement surfacing alloy nickel powder, and 600～650 ℃ of insulations slow cooling afterwards in 2 hours in resistance furnace;

The equipment using has surfacing torch, oxygen cylinder, acetylene cylinder, resistance furnace.

7, finish-milling I: take the first fabrication hole 31, the second fabrication hole 32, the 3rd fabrication hole 33 is clamping benchmark, clamp mould blank two end end faces, finish-milling Hough face, thick finish-milling abnormity inner chamber;

The equipment using is the vertical boring-milling center of 3060VMC Digit Control Machine Tool, and the frock clamp of use is BLM-GZ-TYX02-00 bis-four sides, top rotary jigs.

8, thick finish turning I: the cylindrical that the large end of clamp mould blank has been processed, thick fine turning outer circle, endoporus and each step thereof;

The equipment using is CJK6150 numerically controlled lathe, and the frock clamp of use is the soft dog chuck of φ 300 four paws self-centering hydraulic pressure.

9, thick finish turning II: clamp mould blank small end cylindrical, the thick right boring endoporus each several part of school circle;

The equipment using is CJK6150 numerically controlled lathe, and the frock clamp of use is the soft dog chuck of φ 300 four paws self-centering hydraulic pressure.

10, type in finishing impression: clamp mould blank two end end faces, alignment two side faces, finds type in the finishing impression of center accurately;

The equipment using is SKDX5060 carving machine, and the frock clamp of use is homemade anti-top fixture.

11, interior type polishing: the large end cylindrical of clamp mould blank, school circle polishing;

The equipment using is C620 engine lathe, the frock clamp of use for φ 250 four paws self-centering chucks, the cutter of use be polishing knife bar, machined parameters: rotating speed is 1000r/min, feed speed is 100mm/r.

12, finish-milling II: take the first fabrication hole 31, the second fabrication hole 32, the 3rd fabrication hole 33 is clamping benchmark, compression mould blank two end end faces, finish-milling vacuum tank, air discharge duct, concave, milling is low, the milling of Hough muscle empty, milling is oval; Turn round 180 ° of thick finish-milling locating slots, bore milling vest eye, clothes-hook plane and assemble screw; Turn round thick finish-milling two side faces; Calibration revolution saw blade milling cooling bath etc. remains operation on four sides;

The equipment using is the vertical boring-milling center of 3060VMC Digit Control Machine Tool, and the frock clamp of use is BLM-GZ-TYX02-00 bis-four sides, top rotary jigs.

13, drilling deep hole: folder cylindrical, alignment bad mold joint, finds the center of circle accurately, drilling deep hole;

The equipment using is ZK4050 NC deep hole drilling machine, and the frock clamp of use is homemade special fixture, and the cutter of use is for lengthening fluted drill, and permission linear speed is 45m/min.

14, hinge deep hole: folder cylindrical, alignment bad mold joint, finds the center of circle accurately, hinge deep hole;

The equipment using is WDF500C-2CNC deep hole ream machine, and the frock clamp of use is the special fixture with machine, and the cutter of use is deep hole reamer, and permission linear speed is 40m/min.

15, inner chamber is carved characters: according to customer requirement and drawing requirement, engrave appropriate font and pattern;

The equipment using is X4222A three dimensional pantograph engraving machine, and the frock clamp of use is the homemade fixture that inclines.

16, inner chamber electric spark: engrave appropriate font and pattern according to customer requirement and drawing requirement;

The equipment using is numerical control electric spark machine.

17, bore core: bore each aperture of inner chamber;

The equipment 1 using is Z406B-1 bench drill, and the frock clamp of use is the homemade fixture that inclines; The equipment 2 using is DB703 high speed electric spark small hole processing machine, and the frock clamp of use is the homemade fixture that inclines.

18, boring: bore each hole of residue and comprise inclined hole;

The equipment using is Z4116 bench drill.

19, tapping: attack each screw;

The equipment using is attacked dual-purpose machine for ZS4112C bench drilling.

20, plane mark: carve the signs such as pattern number, model on large end face;

The equipment using is X4222A three dimensional pantograph engraving machine.

21, polishing: die-face (inner chamber) is carried out to light decorations, and surface roughness≤0.2 μ m notes size when polishing;

The equipment using is pneumatic or electronic bistrique, and the grinding tool of use is emery cloth, sand paper.

22, chamfering: each edge chamfering deburring inner chamber of outer surface is retained to acute angle;

23, eventually inspection: each size to finished product mould checks comprehensively, correspondingly makes a record and files for future reference;

24, assembling: dress cooling tube, vexed vacuum screw, upper clothes-hook, mounting handle screw etc.;

25, packing: remove greasy dirt, upper antirust oil, wrapping.

The concrete operation of the embodiment of the present invention two is as follows:

Operation 1～3 is with embodiment mono-;

4, die blank is fixed on Digit Control Machine Tool, determines unified die blank machining benchmark;

The vertical boring-milling center of Digit Control Machine Tool that the model that the equipment using is produced for Taiwan Fu Yu lathe limited company is 3060VMC, the frock clamp of use is BLM-GZ-TYX01-00 brill milling two end fixtures.

Described unified die blank machining benchmark comprises Vehicle Processing center of circle benchmark, datum plane, processing revolution benchmark is bored in milling, and more than determining, three benchmark are realized by boring-milling center first manufacturing procedure, in processing, with these three benchmark, carry out processing mold from start to finish, can not be destroyed.

The generation of three benchmark does not have sequence requirement, but by professional etiquette, is generally first to do datum plane, then does milling and bores processing revolution benchmark, finally does Vehicle Processing center of circle benchmark.

Datum plane 2 is generally to produce by the large end end face of milling die blank, in particular cases also can produce by milling die blank small end end face, such as the shorter situation in the face of cylinder of the large end cylindrical of die blank, be to produce datum plane 2 by the large end end face of milling die blank in the present embodiment; Milling is bored processing revolution benchmark 3 and is produced by generating process hole on die blank two end end faces; Vehicle Processing center of circle benchmark 1 produces by circular interpolation milling or the large end cylindrical of cover boring die blank, is exactly the center of circle of datum plane 2.

By datum plane 2 and milling, bore processing revolution benchmark 3 and determine milling and bore processing revolution axial line, milling is bored processing revolution axial line and is by milling and bores that benchmark 3 is turned round in processing and perpendicular to the straight line of datum plane 2.By datum plane 2 and Vehicle Processing center of circle benchmark 1, determine Vehicle Processing revolution axial line, Vehicle Processing revolution axial line is by Vehicle Processing center of circle benchmark 1 and perpendicular to the straight line of datum plane 2.Milling is bored processing revolution axial line and is turned round the correlation between axial line with Vehicle Processing: be parallel to each other or overlap, all perpendicular to datum plane 2, and and datum plane 2 vertical center line intersect, that is to say that with respect to Vehicle Processing revolution axial line translation certain distance (>=0) on the vertical center line of datum plane 2, just having produced milling bores processing revolution axial line.The small-sized die blank of general processing can make Vehicle Processing revolution axial line and milling brill processing revolution axial line overlap, the die blank of machining large, it is exactly the relation being parallel to each other that Vehicle Processing revolution axial line and milling are bored between processing revolution axial line, in the present embodiment, it is exactly the relation being parallel to each other that Vehicle Processing revolution axial line and milling are bored between processing revolution axial line.

As Fig. 4, Fig. 5, shown in Fig. 6, on the large end end face 10 of die blank, process two the 4th fabrication holes 34, the 5th fabrication hole 35, the 4th fabrication hole 34, the angle of the 5th fabrication hole 35 and the vertical center line of large end end face 10 should >=45 ° and≤75 °, here, be decided to be 60 °, because 60 is 10, 12, 15 multiple, in processing, we wish to try one's best to do fabrication hole by vertical cold hole, vertical cold hole on general die blank is by circle distribution and alternate 10 to 12.5 degree, as long as do not produce interference with other places, the maximum probability that has the cold hole of hanging down on the position of 60 °, so 60 ° is best angle, can certainly select 45 °, 48 °, 50 °, 52 °, 55 °, 62 °, 65 °, 68 °, 70 °, 72, 75 ° of equal angles, only need in processing technology hole, relevant position.On die blank small end end face 11, process two the 6th fabrication holes 36, the 7th fabrication hole 37, the six fabrication holes 36 are coaxial with the center of circle of the 4th fabrication hole 34, the 7th fabrication hole 37 is coaxial with the center of circle of the 5th fabrication hole 35.By the 4th fabrication hole 34, the 5th fabrication hole 35, the 6th fabrication hole 36, the 7th fabrication hole 37, just can determine centre of gyration point 39, by the location compound plate 6 of the location-plate 4 with NC dividing head one end and the other end, just can set up milling and bore processing revolution benchmark 3.

On die blank, generally all needing the vertical cold hole of processing, in production, for position, number, the center-diameter in the vertical cold hole on die blank, do not do unified regulation, is generally by circle distribution and alternate 10 to 12.5 degree, as long as do not produce interference with other places.Although the actual conditions in mould manufacturing enterprise are so at present, for convenient, realize standardized production, we wish to try one's best and do fabrication hole by vertical cold hole, and the cold Kongzui that hangs down thus carries out well standardized designs.Fabrication hole is of a size of φ 7H7, the present embodiment is exactly on the position of the 4th fabrication hole 34, the 5th fabrication hole 35, the 6th fabrication hole 36, the 7th fabrication hole 37, to have the satisfactory cold hole of hanging down, now just can do fabrication hole by vertical cold hole, if do not had, processing technology hole is just passable.

Concrete operations are as follows: the die joint (also claiming joint close face in industry) of die blank of take is clamping datum plane, with three supporting-point location, then the compression mould blank face of cylinder, milling die blank two ends end face, on some punch die blank two end end faces, each hole comprises for determining the hole that needs on the vertical cold hole of benchmark and product design figure etc., the processing of brill milling hinge is used for the vertical cold hole of definite benchmark etc., overlaps the large end cylindrical of boring die blank, milling homalocephalus.

Operation 5～25 is with embodiment mono-.

In order to determine milling, bore processing revolution benchmark 3 and can pass through the vertical center line of the large end end face of die blank, milling is bored processing revolution benchmark 3 preferably by the center of circle of large end end face in theory, but consider the use of cutter, many reasons such as design of fixture, the center of circle that sometimes can only depart from large end end face.In embodiment 1, on the large end end face 10 of die blank, there are two the first fabrication holes 31, the second fabrication hole 32, wherein the second fabrication hole 32 is not on the vertical center line of large end end face, play angle orientation and gearing, on the vertical center line of large end end face, it is exactly rotating central hole to the first fabrication hole 31 so, and its center of circle is milling and bores processing revolution benchmark 3, in embodiment 2, on the large end end face 10 of die blank, there are two the 4th fabrication holes 34, the 5th fabrication hole 35, the 4th fabrication hole 34, the 5th fabrication hole 35 is not on the vertical center line of large end end face, therefore just need location compound plate 6 that plays grafting of processing in addition, on the compound plate 6 of location, there are two positioning pins to insert in two fabrication holes 38 of die blank small end end face 11, allow centre of gyration point 39 still by the vertical center line of large end end face, centre of gyration point 39 is milling and bores processing revolution benchmark 3, therefore the necessary standardization in the center-diameter of fabrication hole and aperture, otherwise, location compound plate does not just have the foundation of design, in practical operation, locate compound plate and before Mould Machining, just determined dimension.

As shown in Fig. 7, Fig. 8, Fig. 9, the use of location-plate is described with regard to the situation of embodiment mono-, in actual adding, can process two die blanks man-hour simultaneously, all can in pairs in pairs or not, what Fig. 7, Fig. 8, Fig. 9 showed is that the fabrication hole that fixture is positioned on die blank is the cold hole of hanging down here, and the vertical cold hole on die blank is that circumference equal dividing distributes and wherein a vertical cold hole be positioned at the situation on the vertical center line of the large end end face 10 of die blank.

As shown in Figure 10, Figure 11, Figure 12, the use of location-plate and location compound plate is described with regard to the situation of embodiment bis-, wherein locate compound plate and play a grafting, in actual adding, can process two die blanks man-hour simultaneously, all can in pairs in pairs or not, what Figure 10 and Figure 11 showed is that the fabrication hole that fixture is positioned on die blank is the cold hole of hanging down here, and the vertical cold hole on mould is that circumference equal dividing distributes and on the vertical center line of the large end end face 10 of die blank without the situation in vertical cold hole.When fabrication hole cannot be used vertical cold hole or not exist the cold Kong Shike that hangs down to come processing technology hole with reference to embodiment bis-, for the location-plate on fixture and location compound plate, because its making simply can design, make temporarily, at embodiment bis-in this case, also can process two location via holes 38 for being connected with location compound plate as shown in Figure 6, can be processed into M6 hole, embodiment bis-just produces centre of gyration point 39.

If there is no or cannot be by vertical cold hole, can be by other holes or processing technology hole in addition.Such as the blank mould having, the cold hole of at all not hanging down, only has several screw holes; Again such as the dies cavity having is square or leg-of-mutton, in designing mould, in order to consider the balance of chilling temperature, the cold hole of hanging down is also and then arranged in square or leg-of-mutton, in these cases, locating hole just can not be used the cold hole of hanging down, just need to be by other holes or other processing technology hole, need interim design and making location-plate and location compound plate location-plate simple with design and the comparison of location compound plate, concrete operations are exactly with reference to embodiment bis-simultaneously.

Each face of step C processing mold blank, comprises Vehicle Processing die blank inside and outside circle, inner chamber and end face, and boring and milling bores revolution processing mold blank inside and outside circle, inner chamber and end face.It is exactly specifically operation 5～24, in milling, bore and add man-hour, utilize boring-milling center equipment and special fixture that scientific and technological content is higher, by milling, bore processing revolution axial line and set multi-work piece coordinate system and realize the three-dimensional processing in four sides, except being not orthogonal to the hole of datum line, other plane, curved surface, hole, groove etc. all can complete the in the situation that of clamped one time in thick fine finishining, that is to say, single operation various in traditional handicraft has been become to the corresponding work step in this operation.

In processing, except selecting the Digit Control Machine Tool boring-milling center that model that Taiwan Fu Yu lathe limited company produces is 3060VMC, can also select the Digit Control Machine Tool boring-milling center that model that the Little Big Man lathe Co., Ltd in Ningxia produces is VTC-200BN.

The Digit Control Machine Tool boring-milling center that the model that the Taiwan Fu Yu lathe limited company that embodiment adopts produces is 3060VMC; requirement to lathe in this technique is: the long 1000mm of table top; the wide 600mm of table top; Z axis destage face is not less than 600mm and differs and be decided to be Z axis stroke; tool magazine capacity is not less than 24; system configuration can be controlled >=4 axles, and can get involved the control of hydraulic system.What cutter adopted is the standard cutter of high rigidity, and configures that tool setting gauge is long to the cutter of cutter for boring-milling center, the mensuration of point of a knife tactical diameter.

Compare traditional processing method, compound milling machine, surface grinding machine, plain-milling machine have been eliminated, still can be for roughing as for engine lathe, in order to enhance productivity, numerically controlled lathe preferably transform hydraulic pressure four paws as or two jaw self-centering chucks (are recommended as Φ 300-Φ 350, while using two pawls, be V-type claw type), claw adopts soft pawl, also can use the numerically controlled lathe with hydraulic system.

The programmer of boring-milling center understands the preferably setting of five-axle linkage and origin, workpiece coordinate of four axles; Machining center operative employee can skilled operation vertical machining centre and is understood the actual use of frock clamp.Programming in practical application to note following some:

A. when using BLM-GZ-TYX01-00 brill milling two end fixtures to carry out first Milling Process to mould product:

The setting of origin system: X, Y, Z axis initial point can be set as the centre of gyration line of fixture and the intersection point of fixture symmetrical center line; By dial gauge school fixture datum plate Y direction, when smoothing, A axle initial point is made as 0 °;

Workpiece coordinate system is set: G54, G55 are set in respectively the die face of the large outer nose circle of part mould blank, and G56, G57 are set in respectively the die face of the little outer nose circle of part mould blank;

It is long that in programming and when operation, need be set cutter, and note length compensation and the radius compensation of cutter, particularly for compensating X, Y, Z value on cylindrical and perpendicular to the hole of centre of gyration line.

B. when using BLM-GZ-TYX02-00D (single head dividing head) or BLM-GZ-TYX02-00S (double end dividing head) two four sides, top rotary jigs to carry out comprehensive process to mould product:

The setting of origin system: X initial point is fixture location-plate left surface, Y initial point, Z initial point are separated time in the symmetry of fixture centre of gyration line or two fixture centre of gyration lines; Install after location-plate, the upper plane of calibration location-plate, and as 0 ° of origin of coordinates of A axle;

Because fixture centre of gyration line and work centre line are two straight lines that are parallel to each other or overlap, thus workpiece coordinate system G54-G59 must be established, X, the desirable same point of Y initial point, but Z initial point is not identical, during programming, should note;

When programming and operation, need set cutter long, and note length compensation and the radius compensation of cutter.

Ball-type rubbing head can be installed on boring-milling center and by High Rotation Speed, carry out rough polishing, to alleviate buffer's labour intensity.

BLM-GZ-TYX01-00 being bored to milling two end fixtures below describes.

This sleeve clamp is for becoming roughcast milling biend, cover boring or circular interpolation milling cylindrical, brill milling to cut with scissors two end locating holes, point each hole of Kong Erduan in vertical boring-mill work.

As shown in Figure 13～Figure 18, for clamping workpiece on Digit Control Machine Tool, designed this sleeve clamp, comprise with lower member: datum plate 91, pressing plate guide pad 92, pressing plate guide pad cover plate 93, pressing plate 94, right gusset piece 95, right gusset piece alignment pin 96, Left-wing Federation's fishplate bar 97, gyroaxis 98, bearing block 99, angle orientation pin 100, bearing block cover plate 101, base plate 102, dividing head keel 103, arm-tie 104, pull bar 105, 2-M8T type nut 106, planar top stroma 107, limited block A108, spacing block 109, limited block cross bar 110, pressing plate refill-unit 111, positioning key 112, positioning key 113.Die blank 132 is clipped on lathe, has four supportings 130 under every die blank, one of them supporting needs to adjust in good time, produces fixture centre of gyration line 131.

BLM-GZ-TYX01-00 bores the using method of milling two end fixtures:

1. the assembling of fixture:

First by combining each part shown in Figure 13～Figure 18 and assembling, adjust fixture, T-shaped required accessory when nut (M16) 114 used for fixture for groove needn't be loaded onto fixture when Fixture assembly.

2. the installation of fixture, step is as follows:

2.1 first in the corresponding T-shaped groove of lathe appropriate locations put into four T-shaped nuts (M16) 114 for groove, fixture is winched on lathe table top, by four hexagon socket cap head screw 115 (GB/T70.1-2000, M16 * 50) put into fixture installing hole and screw in the screw of nut 114 for T-shaped groove, needn't be fastening;

A long limit of 2.2 use dial gauge alignment fixture datum plates 91 fastening hexagon socket cap head screw 115;

2.3 respond to slim hydraulic cylinder 116 (GB/T15622-1995 at magnet ring, MCX-SD40 * 20) respond to and on slim hydraulic cylinder 117 (GB/T15622-1995, MCX-SD40 * 10), connect respectively hydraulic oil pipe (accessing hole on hydraulic cylinder is PT1/4) with magnet ring;

2.4 respond to slim hydraulic cylinder 116 (GB/T15622-1995, MCX-SD40 * 20) and magnet ring at magnet ring responds to and on slim hydraulic cylinder 117 (GB/T15622-1995, MCX-SD40 * 10), connects respectively data wire and be connected with machine tool system;

2.5 connecting data-interface on FK15150B NC dividing head 118 is connected with machine tool system;

Whether each action of 2.6 unlatching lathes gauging fixture is normal.

3. the application of fixture:

3.1 must unload rear fender when processing casual labourer part, are replaced into pressing plate refill-unit 111, and are adjusted and made the stressed uniform balance of arm-tie 104, stable action by hexagon socket cap head screw (M8 * 35) 119;

During 3.2 replacing specification of workpieces:

3.2.1 must adjust hex nut-C level (M16) 120 makes piece-holder firmly and has suitable activity space;

3.2.2 must adjust planar top stroma 107, contact is gone up in position;

3.2.3 hexagonal flush end holding screw (M5 * 5) 121 in adjusting, first adjusts at 3 also with interior hexagonal flush end holding screw (M5 * 5) 122 lockings, another 1 is activity adjustment (each workpiece needs to adjust);

3.2.4 adjust spacing block 109 (limited block A108) and with hexagon socket cap head screw (M6 * 30) 125 lockings, workpiece stretched out on correct position by hexagon socket cap head screw (M8 * 20) 123, hexagon socket cap head screw (M6 * 30) 124; Limited block A108 is used while being the large workpiece of processing, now can directly regulate hexagon socket cap head screw (M8 * 20) 123, hexagon socket cap head screw (M8 * 25) 126.

The clamping of 3.3 workpiece:

Unclamp hexagon socket cap head screw (M8 * 25) 126 and make to turn over and swing on limited block cross bar 110 outside, at pressing plate, insert workpiece 94 times, turn down limited block cross bar 110 fastening hexagon socket cap head screw 126, in adjusting, an expansion bearing in hexagonal flush end holding screw 121, steps on foot-operated some brake control valve and fastens workpiece.

3.4 the points for attention in fixture work:

3.4.1 when carrying out 45 * n degree calibration, in order to make, precision is higher, cutting rigidity is better responded to slim hydraulic cylinder 117 controls with magnet ring, must first unclamp, otherwise can cause the serious consequence of damaging NC dividing head before carrying out calibration;

3.4.2 when carrying out non-45 * n degree calibration, must make magnet ring respond to slim hydraulic cylinder 117 in releasing orientation, and can not eject;

3.4.3 if lathe is closed-loop system, should gets involved magnet ring and respond to the information of slim hydraulic cylinder and control and enroll in program; Make like this frock operation safer.

Below BLM-GZ-TYX02-00S (double end dividing head) two four sides, top rotary jigs are described.

This sleeve clamp is for becoming the thick fine finishining of the surrounding of blank mould except biend (comprise special-shaped inner chamber process) on vertical boring-milling center, but can not process and the uneven hole of end face.

As shown in Figure 19～Figure 24, for clamping workpiece on Digit Control Machine Tool, designed this sleeve clamp, comprise with lower member: base plate 67, bearing block 60, bearing block cover plate 68, sliding axle 73, steel bushing 79, top 72, left locating pin 71, brake block 81, hydraulic cylinder piston knock-off joint 74, location-plate 4, right locating pin 51, right corner degree locating pin 52, location compound plate 6, compound plate locator 54, dividing head keel 69, screw rodb base 76, screw mandrel 65, screw 77, transformation of the way soket head cap screw 80, T-shaped nut (M8) 62 for groove, T-shaped nut (M16) 55 for groove, positioning key 78, positioning key 70.

The using method of BLM-GZ-TYX02-00S (double end dividing head) two four sides, top rotary jigs:

1. the assembling of fixture:

First by combining each part shown in Figure 19～Figure 24 and assembling, adjust fixture, required accessory when T-shaped nut (M16) 55 for groove, location-plate 4, right locating pin 51, right corner degree locating pin 52, location compound plate 6, compound plate locator 54 are used for fixture needn't be loaded onto fixture when Fixture assembly.

2. the installation of fixture, step is as follows:

2.1 first in the corresponding T-shaped groove of lathe appropriate locations put into four T-shaped nuts 55 for groove, fixture is winched on lathe table top, by four hexagon socket cap head screw 56 (GB/T70.1-2000, M16 * 55) put into fixture installing hole and screw in the screw of nut 55 for T-shaped groove, needn't be fastening;

A long limit of 2.2 use dial gauge alignment clamp bottom boards 67 fastening hexagon socket cap head screw 56 (GB/T70.1-2000, M16 * 55);

2.3 respond to slim hydraulic cylinder 57 (GB/T15622-1995 at magnet ring, MCX-SD32 * 5) respond to and on slim hydraulic cylinder 58 (GB/T15622-1995, MCX-SD40 * 20), connect respectively hydraulic oil pipe (accessing hole on hydraulic cylinder is PT1/4) with magnet ring;

2.4 respond to slim hydraulic cylinder 57 (GB/T15622-1995, MCX-SD32 * 5) and magnet ring at magnet ring responds to and on slim hydraulic cylinder 58 (GB/T15622-1995, MCX-SD40 * 20), connects respectively data wire and be connected with machine tool system;

2.5 connect data-interface on FK15140X2 Double end digital control dividing head 82 is connected with machine tool system;

Whether each action of 2.6 unlatching lathes gauging fixture is normal.

3. the application of fixture:

3.1 selecting of location-plate and location compound plate;

3.1.1 as embodiment mono-, have greatly the cold hole of hanging down on the vertical center line of end face 10, need to select the location-plate 4 adapting and pack right locating pin 51 into and right corner degree locating pin 52 on location-plate 4;

3.1.2 as embodiment bis-, vertical cold hole on the vertical center line of large end end face 10, except needs are selected the location-plate 4 adapting and on location-plate 4, pack right locating pin 51 into and right corner degree locating pin 52, also need to select the location compound plate 6 that adapts and on the compound plate 6 of location, pack location compound plate 54 into;

If 3.1.3 cannot use, hang down cold hole or do not have the cold hole of hanging down, needing interim design, make location-plate and location compound plate, and with reference to the way described in 3.1.2.

The prepackage of 3.2 workpiece and the adjustment of fixture:

3.2.1 with T-shaped for groove nut (M8) 62 and hexagon socket cap head screw 63 (GB/T70.1-2000, M8 * 25) selected positioning plate assembly is fixed on dividing head 82 work tops, and calibrate the center of circle with dial gauge; The upper plane of calibration location-plate 4, and as 0 ° of origin of coordinates of A axle;

3.2.2 as described in 3.1.2 and 3.1.3, situation is loaded onto location compound plate assembly at the small end of workpiece;

3.2.3 the corresponding fabrication hole of the large end of workpiece is inserted in to the upper right locating pin 51 of calibration head end location-plate and right corner degree locating pin 52, the internal point on the corresponding fabrication hole of workpiece small end or location compound plate is inserted in to left locating pin 71;

3.2.4 the adjustment on directions X to bearing block:

3.2.4.1 if desired A axle interlock, after loading onto workpiece, first make magnet ring respond to slim hydraulic cylinder 58 in holding out against state, pretension hexagon socket cap head screw 64 (GB/T70.1-2000, M16 * 70), and by screw mandrel 65 impeller-hub bearing 60 light top die blanks, then lock hexagon socket cap head screw 64;

If 3.2.4.2 do not need the interlock of A axle,, on the basis of 3.2.4.1, to return magnet ring and respond to slim hydraulic cylinder 58, bearing block 60 advances 1 again to 2mm;

Points for attention in 3.3 fixture work:

3.3.1 for magnet ring, respond to when slim hydraulic cylinder 57 (GB/T15622-1995, MCX-SD32 * 5) is used and should be noted:

3.3.1.1 when the interlock of A axle or calibration, must unclamp magnet ring and respond to slim hydraulic cylinder 57, otherwise can cause the serious consequence of damaging NC dividing head or fixture, and A axle when interlock can only use as light cut or fine finishining, can not carry out using under (as roughing, the high-rate cutting) states such as large cutting output, the large cutting moment of torque and large cutting force;

3.3.1.2 when A axle does not need to link, should with magnet ring, respond to slim hydraulic cylinder 57 brakes as far as possible, to alleviate the burden of NC dividing head, when NC dividing head (being A axle) carries out calibration, must make magnet ring respond to slim hydraulic cylinder 57 and respond to slim hydraulic cylinder 58 in releasing orientation with magnet ring, otherwise can cause the serious consequence of damaging NC dividing head or fixture.

Points for attention when 3.3.2 programming is with operation:

3.3.2.1 origin is set: X initial point is fixture location-plate left surface, and Y initial point, Z initial point are fixture centre of gyration line;

3.3.2.2 because fixture centre of gyration line is two straight lines of (or coincidence) that are parallel to each other with work centre line, thus workpiece coordinate system (G54-G59) established, X, the desirable same point of Y initial point, but Z initial point is not identical, during programming, should note;

When 3.3.2.3 programming is with operation, need set cutter long, and note length compensation and the radius compensation of cutter;

3.3.2.4 two kinds of magnet rings respond to slim hydraulic cylinder by machine tool system by solenoid control, therefore should together enroll program when programming; If lathe is closed-loop system, should gets involved magnet ring and respond to the information of slim hydraulic cylinder and control and enroll in program; Make like this frock operation safer.

The dismounting of 3.4 workpiece:

When workpiece is installed, should make magnet ring respond to slim hydraulic cylinder 58 in returning state, now workpiece still can not directly be loaded onto fixture, at this moment needs with hand propelled top 72, then press step installation described in 3.2.3; During dismounting, should make magnet ring respond to slim hydraulic cylinder 58 in returning state, then workpiece can be pulled up in promotion top 72.

The using method of BLM-GZ-TYX02-00D bis-top four sides rotary jigs (single head dividing head) is with reference to the using method of BLM-GZ-TYX02-00S bis-top four sides rotary jigs (double end dividing head).

Claims (7)

1. a processing method for container glass mold, comprises A casting die blank; It is characterized in that, further comprising the steps of:

B is fixed on die blank on Digit Control Machine Tool, determines unified die blank machining benchmark;

Described unified die blank machining benchmark comprises datum plane, and processing revolution benchmark is bored in milling, Vehicle Processing center of circle benchmark, and datum plane produces by milling die blank one end end face; Milling is bored processing revolution benchmark and is produced by generating process hole on die blank two end end faces; Vehicle Processing center of circle benchmark produces by circular interpolation milling or cover boring die blank one end cylindrical;

By datum plane and milling, bore processing revolution benchmark and determine milling brill processing revolution axial line, by datum plane and Vehicle Processing center of circle benchmark, determine Vehicle Processing revolution axial line, described milling is bored processing revolution axial line and is parallel to each other or overlaps with Vehicle Processing revolution axial line, both are all perpendicular to described datum plane, and and the vertical center line of described datum plane intersect;

Each face of C processing mold blank.

2. the processing method of a kind of container glass mold according to claim 1, is characterized in that, Vehicle Processing center of circle benchmark produces by circular interpolation milling or the large end cylindrical of cover boring die blank.

3. the processing method of a kind of container glass mold according to claim 2, it is characterized in that, described datum plane produces by the large end end face of milling die blank (10), at upper the first fabrication hole (31) that generates of large end end face (10), the second fabrication hole (32), the first fabrication hole (31) is positioned on the vertical center line of large end end face (10), the second fabrication hole (32) center of circle and the large end line in the end face center of circle and angle >=45 of described large end end face vertical center line ° and≤75 °, at the 3rd fabrication hole (33) of the upper generation of die blank small end end face (11), the center of circle of the center of circle of the 3rd fabrication hole (33) and the first fabrication hole (31) is coaxial.

4. the processing method of a kind of container glass mold according to claim 3, is characterized in that, the first fabrication hole (31) equates with the distance of the second fabrication hole (32) to large end end face (10) center of circle.

5. the processing method of a kind of container glass mold according to claim 2, it is characterized in that, described datum plane produces by the large end end face of milling die blank (10), at upper the 4th fabrication hole (34) that generates of large end end face (10), the 5th fabrication hole (35), the 4th fabrication hole (34), the 5th fabrication hole (35) center of circle and the large end line in the end face center of circle and angle >=45 of described large end end face vertical center line ° and≤75 °, at upper the 6th fabrication hole (36) that generates of die blank small end end face (11), the 7th fabrication hole (37), the center of circle of the 6th fabrication hole (36) is coaxial with the center of circle of the 4th fabrication hole (34), the center of circle of the 7th fabrication hole (37) is coaxial with the center of circle of the 5th fabrication hole (35).

6. the processing method of a kind of container glass mold according to claim 5, it is characterized in that, the 4th fabrication hole (34) center of circle is with the 5th fabrication hole (35) center of circle to holding greatly the distance in end face (10) center of circle to equate, the 4th fabrication hole (34) is being held on the same circle center line of end face greatly with the 5th fabrication hole (35).

7. according to the processing method of a kind of container glass mold described in the arbitrary claim of claim 1 to 6, it is characterized in that, step C comprises: Vehicle Processing die blank inside and outside circle, inner chamber and end face, boring and milling bores revolution processing mold blank inside and outside circle, inner chamber and end face.