CN113264662B - Thick glass cup forming mechanism - Google Patents

Abstract

The invention discloses a thick glass cup forming mechanism in the technical field of glassware production and manufacturing, which comprises a forming machine body, wherein a material containing mechanism is fixedly arranged at the top of the forming machine body and comprises a feeding mechanism and an ejection mechanism, the material containing plate is rotatably arranged at the top of the material containing mechanism, four lower die seats which are distributed in a circular shape are fixedly arranged at the top of the material containing plate, a hydraulic rod is fixedly arranged at the top of the forming machine body, a connecting plate is fixedly arranged at the bottom end of the hydraulic rod and is positioned right above the material containing plate, and a cooling cylinder and a mold pressing core are fixedly arranged at the bottom of the connecting plate. The invention can cool the formed glass cup in the process of pressing the glass blank body to ensure that the glass cup can be rapidly cooled and formed, can rapidly separate the glass cup from the pressing mould, is convenient for workers to unload, can continuously press and form the glass blank body at one time, and avoids the process of secondary processing.

Description

Thick glass cup forming mechanism

Technical Field

The invention relates to the technical field of glassware production and manufacturing, in particular to a thick glass cup forming mechanism.

Background

High borosilicate glass is a special glass material with low expansion rate, high temperature resistance, high strength, high hardness, high light transmittance and high chemical stability, and is widely applied to industries such as solar energy, chemical industry, medical packaging, electric light sources, craft ornaments and the like due to excellent performance. The cup made of the high borosilicate glass is more resistant to high temperature and low temperature than the traditional glass, so that the high borosilicate glass is more and more widely used.

When the existing high borosilicate glass cup is manufactured, a certain amount of high borosilicate glass which is softened at high temperature is firstly placed in a die cavity by adopting a press molding process, and then the high borosilicate glass in the die cavity is extruded and molded by utilizing a press mold core.

The available glass forming equipment has the following defects:

1. the glass cup formed in the pressing process of the glass cup is easy to clamp in the die cavity or on the die pressing core and is not easy to take out, and the glass cup which cannot be pressed and formed cannot be rapidly cooled and is easy to deform when being taken out from the die cavity;

at present, glass blanks are generally fed into a forming machine through a conveying belt, and due to the fact that the strength of the conveying belt is limited, deformation is easy to occur when pressure is applied, so that a mold cavity or a mold core cannot be completely attached in place, and a glass cannot be formed in place at one time.

Disclosure of Invention

The invention aims to provide a thick glass forming mechanism to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a thick glass cup forming mechanism comprises a forming machine body, wherein a material containing mechanism is fixedly mounted at the top of the forming machine body and comprises a feeding mechanism and an ejection mechanism, a material containing disc is rotatably mounted at the top of the material containing mechanism, four lower die seats which are distributed in a circular shape are fixedly mounted at the top of the material containing disc, a hydraulic rod is fixedly mounted at the top of the forming machine body, a connecting plate is fixedly mounted at the bottom end of the hydraulic rod and is positioned right above the material containing disc, a cooling cylinder and a die pressing core are fixedly mounted at the bottom of the connecting plate and are positioned right above the two corresponding lower die seats, a refrigeration mechanism is fixedly mounted at one side of the forming machine body and is connected with the cooling cylinder, the ejection mechanism comprises four cross bars and the ejection rod, and the four cross bars are fixedly connected with a support column, the top of horizontal bar is rotated and is installed the second guide pulley, the ejector pin slides and runs through square board, the bottom fixed mounting of ejector pin has the bottom plate, the bottom of bottom plate is rotated and is installed the third guide pulley, the sliding sleeve is equipped with the annular piece on the ejector pin, the top of annular piece and the bottom fixed connection of square board are in the same place, one side fixed mounting that annular piece and bottom plate are close to each other has same spring, the spring sliding sleeve is established on the ejector pin, the equal fixed mounting in one side that horizontal bar and bottom plate are close to each other has the mount pad, second guide pulley and third guide pulley rotate with the mount pad that corresponds respectively and link together, equal fixed cover is equipped with cushion washer on second guide pulley and the third guide pulley.

Preferably: the material containing mechanism further comprises a rectangular box, a square plate is fixedly mounted at the top of the rectangular box, a first annular groove is formed in the bottom of the material containing plate, four first guide wheels which are circularly distributed are rotatably mounted at the top of the square plate, and the four first guide wheels are all in rolling connection with the inner wall of the first annular groove.

Preferably: the feed mechanism includes that the top is open-ended support column, the top of support column runs through square board and is in the same place with the bottom fixed connection of containing tray, it has first gear to run through fixed mounting on the support column.

Preferably: the bottom of square board is rotated and is installed the pivot, run through fixed mounting in the pivot and have second gear and driven plate, one side fixed connection that second gear and driven plate are close to each other is in the same place, and second gear and first gear engagement are in the same place, four recesses that are circular distribution have been seted up on the driven plate, fixed mounting has the motor on the bottom inner wall of rectangle case, fixed mounting has the horizontal pole on the output shaft of motor, the top fixed mounting of horizontal pole has the round bar, the round bar runs through the recess that corresponds and is in the same place with the inner wall sliding connection who corresponds the recess.

Preferably: the square plate is provided with two rotating holes, the bearings are fixedly mounted in the two rotating holes, the ejector rod penetrates through the inner rings of the corresponding bearings and is in interference fit with the inner rings of the corresponding bearings, the bottom ends of the supporting columns are nested with balls, and the balls are rotatably connected with the inner wall of the bottom of the rectangular box.

Preferably: the gear ratio of the first gear to the second gear is 1: 1, and the included angle between two adjacent grooves on the driven disc is 90 degrees.

Preferably: set up four ejection holes that are circular distribution on the containing tray, the die holder includes interior die, cylinder and ejecting dish, interior die and containing tray fixed connection are in the same place, and just the indent mould is located and corresponds directly over the ejection hole, cylinder and ejecting dish respectively with the inner wall sliding connection of ejection hole and interior die together, and cylinder and one side fixed connection that the ejecting dish is close to each other are in the same place, the slide opening has been seted up on the square board, the top of ejector rod slides and runs through slide opening and ejection hole and be in the same place with cylindrical bottom fixed connection.

Preferably: the refrigerating mechanism comprises a case, a micro refrigerator and an air blower are fixedly mounted in the case, the cooling cylinder, the die core and the refrigerator are connected with the air blower through guide pipes, the model of the micro refrigerator is DAKC-27, and air holes distributed in an annular shape are uniformly distributed in the cooling cylinder.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the invention, in the process of forming the pressed glass blank, the low-temperature gas generated by the micro refrigerator is conveyed into the cooling cylinder and the pressing die core by the blower in the refrigerating mechanism through the guide pipe, the low-temperature gas in the cooling cylinder 7 is discharged through the vent hole and blown to the formed glass cup, so that the glass cup can be rapidly cooled and formed, the glass cup and the pressing die can be rapidly separated, and the cooled and formed glass cup is ejected from the inside, so that the unloading is convenient for workers.

2. The invention can continuously press and form the glass blank body at one time, avoids secondary processing, has fewer working procedures and improves the operating efficiency.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a first perspective view of the present invention;

FIG. 2 is a second perspective view of the present invention;

FIG. 3 is a schematic structural view of a material containing mechanism, a material containing disc and a lower die holder in the invention;

FIG. 4 is a schematic structural diagram of a feeding mechanism and an ejection mechanism according to the present invention;

FIG. 5 is a schematic structural view of a connecting plate, a cooling cylinder and a die core according to the present invention;

FIG. 6 is a schematic view of the mechanism of the tray of the present invention;

FIG. 7 is a schematic structural view of the lower die holder of the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

1-a forming machine body, 2-a material containing mechanism, 21-a rectangular box, 22-a material loading mechanism, 221-a support column, 222-a first gear, 223-a rotating shaft, 224-a second gear, 225-a driven plate, 226-a groove, 227-a motor, 228-a cross rod, 229-a round rod, 23-an ejection mechanism, 231-a cross bar, 232-a second guide wheel, 233-an ejection rod, 234-a bottom plate, 235-a third guide wheel, 236-an annular block, 237-a spring, 24-a square plate, 25-a slide hole, 3-a material containing plate, 31-an ejection hole, 33-a first annular groove, 34-a first guide wheel, 4-a lower die holder, 41-an inner concave die, 42-a cylinder, 43-an ejection plate and 5-a hydraulic rod, 6-connecting plate, 7-cooling cylinder, 8-die pressing core and 9-refrigerating mechanism.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7, the present invention provides a technical solution: a thick glass cup forming mechanism comprises a forming machine body 1, a material containing mechanism 2 is fixedly installed at the top of the forming machine body 1, the material containing mechanism 2 comprises a feeding mechanism 22 and an ejection mechanism 23, a material containing tray 3 is rotatably installed at the top of the material containing mechanism 2, four lower die holders 4 which are distributed in a circular shape are fixedly installed at the top of the material containing tray 3, a hydraulic rod 5 is fixedly installed at the top of the forming machine body 1, a connecting plate 6 is fixedly installed at the bottom end of the hydraulic rod 5, the connecting plate 6 is positioned right above the material containing tray 3, a cooling cylinder 7 and a pressing die core 8 are fixedly installed at the bottom of the connecting plate 6, the cooling cylinder 7 and the pressing die core 8 are positioned right above the two corresponding lower die holders 4, a refrigerating mechanism 9 is fixedly installed at one side of the forming machine body 1, the refrigerating mechanism 9 is connected with the cooling cylinder 7, the ejection mechanism 23 comprises four cross bars 231 and an ejection rod 233, and the four cross bars 231 are fixedly connected with a support column 221, second guide wheel 232 is installed in the top rotation of horizontal bar 231, liftout pole 233 slides and runs through square board 24, the bottom fixed mounting of liftout pole 233 has bottom plate 234, the bottom of bottom plate 234 is rotated and is installed third guide wheel 235, the cover is equipped with annular piece 236 on the liftout pole 233 in the slip cap, the top of annular piece 236 and the bottom fixed connection of square board 24 are in the same place, one side fixed mounting that annular piece 236 and bottom plate 234 are close to each other has same spring 237, spring 237 slip cap is established on liftout pole 233, the equal fixed mounting in one side that horizontal bar 231 and bottom plate 234 are close to each other has the mount pad, second guide wheel 232 and third guide wheel 235 rotate with the mount pad that corresponds respectively and link together, equal fixed cap is equipped with the cushion washer on second guide wheel 232 and the third guide wheel 235.

Wherein, flourishing material mechanism 2 still includes rectangle case 21, and rectangle case 21's top fixed mounting has square board 24, and first ring channel 33 has been seted up to the bottom of containing tray 3, and square board 24's top is rotated and is installed four first guide pulleys 34 that are circular distribution, and four first guide pulleys 34 all are connected with the inner wall roll of first ring channel 33.

Further, the four first guide wheels 34 can support the material containing tray 3 left and right, so that the material containing tray 3 is prevented from being deflected and deformed due to pressure.

The feeding mechanism 22 includes a supporting column 221 with an opening at the top, the top end of the supporting column 221 penetrates through the square plate 24 and is fixedly connected with the bottom of the material containing tray 3, and a first gear 222 penetrates through and is fixedly mounted on the supporting column 221.

Further, the support column 221 can not only drive the material containing tray 3 to rotate, but also can support the material containing tray 3.

Wherein, the bottom of square board 24 is rotated and is installed pivot 223, run through fixed mounting on the pivot 223 and have second gear 224 and driven plate 225, one side fixed connection that second gear 224 and driven plate 225 are close to each other is in the same place, and second gear 224 and first gear 222 meshing are in the same place, four recesses 226 that are circular distribution have been seted up on the driven plate 225, fixed mounting has motor 227 on the bottom inner wall of rectangle case 21, fixed mounting has horizontal pole 228 on the output shaft of motor 227, the top fixed mounting of horizontal pole 228 has round bar 229, round bar 229 runs through corresponding recess 226 and with the inner wall sliding connection that corresponds recess 226 in the same place.

Further, the motor 227 is started, the motor 227 drives the cross rod 228 to rotate, the cross rod 228 drives the round rod 229 to rotate into the adjacent groove 226 from one groove 226 along with the rotation of the cross rod 228 for one circle, the driven disc 225 rotates 90 degrees in the process, the driven disc 225 drives the first gear 222 to rotate through the second gear 224, the first gear 222 drives the material containing disc 3 to rotate 90 degrees through the supporting column 221, the lower die holder 4 containing the glass blank body rotates to be right below the pressing die core 8, and the lower die holder 4 pressed into the glass cup rotates to be right below the column cooling cylinder 7, so that the pressing operation and the cooling and shaping operation can be simultaneously performed.

Wherein, square 24 is last to have seted up two and to have rotated the hole, and two rotate downthehole equal fixed mounting have a bearing, and knock-out rod 233 runs through the inner circle that corresponds the bearing and is in the same place with the inner circle interference fit that corresponds the bearing, and the bottom nestification of support column 221 has the ball, and the ball links together with the bottom inner wall rotation of rectangle case 21.

Further, the balls not only can reduce the friction between the supporting column 221 and the inner wall of the bottom of the rectangular box 21, but also can play a supporting role for the supporting column 221.

Wherein, the gear ratio of the first gear 222 and the second gear 224 is 1: 1, and the included angle between two adjacent grooves 226 on the driven disc 225 is 90 degrees.

Further, the included angle between two adjacent grooves 226 is 90 degrees, so that the driven plate 225 can be driven to rotate 90 degrees when the grooves 226 rotate for one circle, and because the gear ratio of the first gear 222 to the driven plate 225 is 1: 1, the material containing plate 3 can rotate 90 degrees along with the driven plate 225 through the supporting column 221, so that the glass blank can rotate to the position right below the press mold core 8, and the glass cup formed by pressing is positioned right below the cooling cylinder 7.

Wherein, ejection mechanism 23 includes four crossbands 231 and liftout rod 233, the one end and the support column 221 fixed connection that four crossbands 231 are close to each other are in the same place, the top of crossband 231 is rotated and is installed second guide pulley 232, liftout rod 233 slides and runs through square board 24, the bottom fixed mounting of liftout rod 233 has bottom plate 234, the bottom of bottom plate 234 is rotated and is installed third guide pulley 235, sliding sleeve is equipped with annular piece 236 on the liftout rod 233, the top of annular piece 236 and the bottom fixed connection of square board 24 are in the same place, one side fixed mounting that annular piece 236 and bottom plate 234 are close to each other has same spring 237, spring 237 sliding sleeve is established on liftout rod 233.

Furthermore, one of the cross bars 231 rotates to a position below the third guide wheel 235, the third guide wheel 235 drives the ejecting rod 233 to move upwards through the bottom plate 234, and the ejecting rod 233 ejects the glass, which is cooled and shaped in the concave die 41, out of the concave die 41 through the matching of the cylinder 42 and the ejecting disk 43, so that the glass is conveniently separated from the lower die holder 4.

Wherein, the equal fixed mounting in one side that horizontal bar 231 and bottom plate 234 are close to each other has the mount pad, and second guide pulley 232 and third guide pulley 235 rotate with the mount pad that corresponds respectively and link together, all fix on second guide pulley 232 and the third guide pulley 235 and overlap and be equipped with cushion ring.

Wherein, set up four ejecting holes 31 that are circular distribution on the containing tray 3, lower die holder 4 includes interior die 41, cylinder 42 and ejecting dish 43, interior concave mould 41 and containing tray 3 fixed connection are in the same place, and interior concave mould 41 is located and corresponds ejecting hole 31 directly over, cylinder 42 and ejecting dish 43 respectively with ejecting hole 31 and the inner wall sliding connection of interior concave mould 41 together, and cylinder 42 and one side fixed connection that ejecting dish 43 is close to each other are in the same place, the slide opening 25 has been seted up on the square board 24, the top of ejector pin 233 slides and runs through slide opening 25 and ejecting hole 31 and with cylinder 42's bottom fixed connection together.

The refrigerating mechanism 9 comprises a case, a micro refrigerator and an air blower are fixedly arranged in the case, a cooling cylinder 7, a pressing die core 8 and the refrigerator are connected together through a guide pipe and the air blower, the model of the micro refrigerator is DAKC-27, and air holes distributed in an annular shape are uniformly distributed on the cooling cylinder 7.

Further, carry into cooling section of thick bamboo 7 and moulding-die core 8 through the pipe with the produced low-temperature gas of micro-refrigerator through the air-blower in the refrigeration mechanism 9 in, the low-temperature gas in the cooling section of thick bamboo 7 is discharged and is blown to fashioned glass through the air vent, makes its cooling design that can be quick, and the cold air in the moulding-die core 8 can last to the moulding-die core 8 cool down, avoids appearing the condition that the temperature is too high after pressing die core 8 and the glass body of high temperature last time contact.

When the glass cup manufacturing device works, when a glass cup is manufactured, high-temperature soft glass blanks can be placed in two adjacent lower die seats 4, then the connecting plate 6 is controlled to move downwards through the hydraulic rod 5, the connecting plate 6 drives the pressing die core 8 to move downwards and to be matched with the lower die seat 4 below, so that the lower die seats 4 and the pressing die core 8 can be matched with each other and the glass blanks can be extruded into the shape of the glass cup, then the material containing plate 3 is driven to rotate through the material containing mechanism 2, the glass cups in the upper die seat 4 and the lower die seat 4 of the material containing plate 3 are positioned under the cooling cylinder 7, then the other glass blank is placed in the lower die seat 4 under the pressing die core 8, then the connecting plate 6 is driven to move downwards through the hydraulic rod 5, the pressing die core 8 can extrude the glass blanks into the glass cups, the cooling cylinder 7 enters the formed glass cups, and at the moment, a low-temperature gas generated by a micro refrigerator is conveyed into the cooling cylinder 7 and the pressing die core 8 through a guide pipe by an air blower in the refrigerating mechanism 9 The low-temperature gas in the cooling cylinder 7 is discharged through the vent holes and blown to the formed glass cup, so that the glass cup can be rapidly cooled and shaped, the cold air in the pressing mold core 8 can continuously cool the pressing mold core 8, the situation that the temperature is too high after the pressing mold core 8 and the high-temperature glass blank are contacted with each other for a while is avoided, then a new glass blank is placed in the lower mold base 4 close to one side of an operator, then the motor 227 is started, the motor 227 drives the cross rod 228 to rotate, the cross rod 228 drives the round rod 229 to rotate from one groove 226 into the other adjacent groove 226 along with the rotation of the cross rod 228 for one circle, in the process, the driven disk 225 rotates 90 degrees, the driven disk 225 drives the first gear 222 to rotate through the second gear 224, the first gear 222 drives the material containing disk 3 to rotate 90 degrees through the support column 221, the lower mold base 4 containing the glass blank rotates to the right below the pressing mold core 8, the lower die holder 4 for pressing the glass cup rotates right below the column cooling cylinder 7, then the cooling cylinder 7 and the die core 8 move downwards again, so that the glass blank is pressed and formed, meanwhile, the glass cup is cooled and formed, then the motor 227 is controlled to rotate for one circle again, so that the supporting column 221 can drive the material containing tray 3 to rotate 90 degrees again, in the process, one cross bar 231 rotates to the position below the third guide wheel 235, the third guide wheel 235 drives the ejection rod 233 to move upwards through the bottom plate 234, the ejection rod 233 ejects the glass cup cooled and formed in the concave die 41 out of the concave die 41 through the matching of the column 42 and the ejection disk 43, the glass cup and the lower die holder 4 are conveniently separated, then the glass blank is placed in the lower die holder 4 for taking out the glass cup, the operation is a stroke, and the operation is repeated, so that the glass cup can be pressed continuously.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims (3)

1. The utility model provides a thick glass forming mechanism, includes make-up machine body (1), its characterized in that: the top fixed mounting of make-up machine body (1) has flourishing material mechanism (2), flourishing material mechanism (2) includes feed mechanism (22) and ejection mechanism (23), the top of flourishing material mechanism (2) is rotated and is installed flourishing charging tray (3), the top fixed mounting of flourishing charging tray (3) has four die holders (4) that are circular distribution, the top fixed mounting of make-up machine body (1) has hydraulic stem (5), the bottom fixed mounting of hydraulic stem (5) has connecting plate (6), connecting plate (6) are located flourishing charging tray (3) directly over, the bottom fixed mounting of connecting plate (6) has cooling section of thick bamboo (7) and pressure mold core (8), cooling section of thick bamboo (7) and pressure mold core (8) are located directly over corresponding two die holders (4), one side fixed mounting of make-up machine body (1) has refrigerating mechanism (9), the refrigeration mechanism (9) is connected with the cooling barrel (7), the ejection mechanism (23) comprises four transverse bars (231) and an ejection rod (233), one ends of the four transverse bars (231) are fixedly connected with a same supporting column (221), the other ends of the four transverse bars (231) are rotatably provided with second guide wheels (232), the ejection rod (233) penetrates through a square plate (24) in a sliding manner, a bottom plate (234) is fixedly arranged at the bottom end of the ejection rod (233), a third guide wheel (235) is rotatably arranged at the bottom of the bottom plate (234), an annular block (236) is slidably sleeved on the ejection rod (233), the top of the annular block (236) is fixedly connected with the bottom of the square plate (24), a spring (237) is fixedly arranged at one side of the annular block (236) and the bottom plate (234) close to each other, and the spring (237) is slidably sleeved on the ejection rod (233), mounting seats are fixedly mounted on the side, close to each other, of each cross bar (231) and the corresponding side, of each bottom plate (234), the second guide wheel (232) and the corresponding third guide wheel (235) are respectively connected with the corresponding mounting seats in a rotating mode, and buffering gaskets are fixedly sleeved on the second guide wheel (232) and the corresponding third guide wheel (235); the material containing mechanism (2) further comprises a rectangular box (21), a square plate (24) is fixedly installed at the top of the rectangular box (21), a first annular groove (33) is formed in the bottom of the material containing plate (3), four first guide wheels (34) which are distributed in a circular shape are rotatably installed at the top of the square plate (24), and the four first guide wheels (34) are all in rolling connection with the inner wall of the first annular groove (33); the feeding mechanism (22) comprises a supporting column (221) with an opening at the top, the top end of the supporting column (221) penetrates through the square plate (24) and is fixedly connected with the bottom of the material containing tray (3), and a first gear (222) penetrates through and is fixedly mounted on the supporting column (221); a rotating shaft (223) is rotatably mounted at the bottom of the square plate (24), a second gear (224) and a driven disc (225) are fixedly mounted on the rotating shaft (223) in a penetrating mode, one side, close to each other, of the second gear (224) and the driven disc (225) are fixedly connected together, the second gear (224) is meshed with the first gear (222), four grooves (226) distributed in a circular mode are formed in the driven disc (225), a motor (227) is fixedly mounted on the inner wall of the bottom of the rectangular box (21), a cross rod (228) is fixedly mounted on an output shaft of the motor (227), a round rod (229) is fixedly mounted at the top of the cross rod (228), and the round rod (229) penetrates through the corresponding groove (226) and is connected with the inner wall of the corresponding groove (226) in a sliding mode; set up four liftout hole (31) that are circular distribution on containing tray (3), die holder (4) are including interior die (41), cylinder (42) and liftout dish (43), interior die (41) and containing tray (3) fixed connection are in the same place, and indent mould (41) are located corresponding liftout hole (31) directly over, cylinder (42) and liftout dish (43) are in the same place with the inner wall sliding connection of liftout hole (31) and indent mould (41) respectively, and cylinder (42) and one side fixed connection that liftout dish (43) are close to each other are in the same place, sliding hole (25) have been seted up on square board (24), the top of liftout pole (233) slides and runs through sliding hole (25) and liftout hole (31) and is in the same place with the bottom fixed connection of cylinder (42).

2. The thick glass forming mechanism of claim 1, wherein: the gear ratio of the first gear (222) to the second gear (224) is 1: 1, and the included angle between two adjacent grooves (226) on the driven disc (225) is 90 degrees.

3. The thick glass forming mechanism of claim 1, wherein: the refrigerating mechanism (9) comprises a case, a micro refrigerator and an air blower are fixedly mounted in the case, the cooling cylinder (7), the die pressing core (8) and the refrigerator are all connected with the air blower through a guide pipe, the model of the micro refrigerator is DAKC-27, and air holes which are distributed annularly are uniformly distributed in the cooling cylinder (7).

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