CN114057382B - Precision mould pressing glass aspheric lens manufacturing equipment - Google Patents

Abstract

The invention relates to manufacturing equipment, in particular to equipment for manufacturing a precision-molded glass aspheric lens. The invention provides the manufacturing equipment for the precision die-pressed glass aspheric lens, which can clamp the glass lens, reduce errors, save resources and reduce manufacturing cost. A precision press molded glass aspheric lens manufacturing apparatus comprising: the front side and the rear side of the top of the bottom plate are respectively provided with a first support frame; the first sliding module is arranged between the right sides of the two first support frames in a sliding manner; and the second sliding module is arranged between the left sides of the two first supporting frames in a sliding manner. People place the glass lens between two slip clamps earlier, do not exert the force to the slip clamp afterwards, under second reset spring's reset action, the slip clamp is moved to the inboard and is pressed from both sides tightly the glass lens, so alright carry out firm manufacturing more to the glass lens, reduce the error.

Description

Precision mould pressing glass aspheric lens manufacturing equipment

Technical Field

The invention relates to manufacturing equipment, in particular to equipment for manufacturing a precision-molded glass aspheric lens.

Background

The aspherical mirror is a lens whose surface is not a spherical surface or a cylindrical surface, and in photography, the lens comprises an aspherical optical element, the radian of the surface of the aspherical lens is different from that of a common spherical lens, and the curved surface of the lens needs to be changed in order to pursue the thinness of the lens.

Traditional lens adopts the mode processing of grinding, it is difficult to produce the aspheric surface lens of high accuracy from this, therefore glass mould pressing is the optical lens technique most suitable for making the aspheric surface at present, utilize glass mould pressing method, but current manufacture equipment is when carrying out the mould pressing to the glass lens, generally place the glass lens on the workstation, contact through stamping die and glass lens, alright extrude into the aspheric surface lens to the glass lens, the glass lens is under the state that does not press from both sides tightly, stamping die extrudees the glass lens, lead to the glass lens after the shaping to have certain error, make the follow-up unable matching of some good glass lenses of shaping, so just waste more resource, manufacturing cost is higher.

Therefore, a glass aspheric lens manufacturing device capable of clamping a glass lens, reducing errors, saving resources and reducing manufacturing cost through precision die pressing is needed.

Disclosure of Invention

Therefore, the invention aims to overcome the defects that the formed glass lens has certain errors, wastes resources and has higher manufacturing cost because the glass lens is generally placed on a workbench and is not directly clamped by the conventional manufacturing equipment, and provides the precision die-pressed glass aspheric lens manufacturing equipment which can clamp the glass lens, reduce the errors, save the resources and reduce the manufacturing cost.

In order to solve the problem of complaints, the invention is realized by the following technical scheme:

a precision press-molded glass aspherical lens manufacturing apparatus comprising:

the front side and the rear side of the top of the bottom plate are respectively provided with a first support frame;

the first sliding module is arranged between the right sides of the two first support frames in a sliding manner;

the second sliding module is arranged between the left sides of the two first supporting frames in a sliding manner;

the first fixing blocks are arranged inside the first sliding module and the second sliding module;

the first sliding die is arranged on the left side of a first fixed block on the right side in a sliding manner, and is in sliding fit with the first sliding module;

a second sliding die is arranged on the right side of the first fixed block on the left side in a sliding manner and is in sliding fit with the second sliding module;

the first reset spring is arranged between the first sliding die and the first right fixed block, and the first reset spring is arranged between the second sliding die and the first left fixed block;

the bottom parts of the first sliding die and the second sliding die are respectively provided with a first connecting block, the first connecting block on the right side is in sliding fit with the first sliding module, and the first connecting block on the left side is in sliding fit with the second sliding module;

the middle of the top of the bottom plate is provided with a clamping mechanism for clamping the lens;

the placing mechanism is arranged in the middle of the top of the bottom plate and matched with the first sliding die and the second sliding die.

As a preferable aspect of the present invention, the clamping mechanism includes:

the front side and the rear side of the middle of the top of the bottom plate are respectively provided with a supporting block;

the upper parts of the two supporting blocks are both provided with sliding clamps in a sliding manner;

and the second reset springs are arranged between the two sliding clamps and the supporting block at the same side and are respectively wound on the sliding clamps at the same side.

As a preferable aspect of the present invention, the placing mechanism includes:

the left side and the right side of the middle of the top of the bottom plate are respectively provided with a second fixed block;

the placing plate is arranged between the upper parts of the two second fixing blocks in a sliding manner;

the lower parts of the outer sides of the two second fixing blocks are both provided with a first wedge block in a sliding mode, and the two first wedge blocks are connected with the placing plate;

the supporting springs are arranged between the two first wedge-shaped blocks and the second fixing block on the same side, and the two supporting springs are located inside the second fixing block on the same side;

first wedge, first slip module and second slip module bottom all are equipped with first wedge, and two first wedges move to the inboard and all contact with the first wedge of homonymy.

As a preferred technical solution of the present invention, the present invention further comprises a transmission mechanism, the transmission mechanism includes:

the left side and the right side of the top of the bottom plate are respectively provided with a supporting plate;

the left side and the right side of the middle of the top of the bottom plate are both provided with a second connecting block;

racks are arranged between the supporting plate on the same side and the upper part of the second connecting block in a sliding manner;

the tops of the outer sides of the two racks are both provided with a second wedge block in a sliding mode, the second wedge block on the left side is in contact fit with the second sliding module, the second wedge block on the right side is in contact fit with the first sliding module, and the two second wedge blocks move inwards and are in contact with the first connecting block on the same side;

the first connecting springs are arranged between the two second wedge-shaped blocks and the racks on the same side;

the motor is arranged in the middle of the top of the bottom plate;

the first gear is arranged on the motor output shaft and meshed with the two racks.

As a preferable technical solution of the present invention, the present invention further includes a control mechanism, the control mechanism including:

the front side and the rear side of the left end of the top of the bottom plate are rotatably provided with rotating rods;

the middle parts of the two rotating rods are respectively provided with a second gear, and the two second gears are meshed with each other;

the middle parts of the two rotating rods are respectively provided with a first roller wheel which is positioned above the second gear;

the top of the rotating rod at the rear side is provided with a rotating wheel;

the front side and the rear side of the left end of the top of the bottom plate are both provided with a connecting frame;

the upper parts of the two connecting frames are rotatably provided with two second rollers through rotating shafts;

the rope, it has the rope all to wind on two first gyro wheels, and two ropes wind respectively and connect on homonymy second gyro wheel, and the other end of two ropes is connected on homonymy slip clamp.

As a preferable technical solution of the present invention, the present invention further includes a chucking mechanism, the chucking mechanism including:

the lower part of the rear side rotating rod is provided with a rotating disc;

the left rear side of the top of the bottom plate is provided with a third fixing block;

the sliding rod is arranged at the top in the third fixing block in a sliding manner;

a fourth reset spring is arranged between the sliding rod and the third fixed block;

the upper part in the sliding rod is provided with a convex block in a sliding way, and the convex block is tightly matched with the rotating disc in a clamping way;

the second connecting spring is arranged between the convex block and the sliding rod;

the rear left side of the top of the bottom plate is provided with a fixed rod, and the fixed rod is positioned on the right side of the third fixed block;

the sliding plate is arranged on the upper part of the fixed rod in a sliding manner;

and a third reset spring is arranged between the sliding plate and the fixed rod, and the sliding plate is connected with the sliding rod.

As a preferred technical solution of the present invention, the present invention further includes a cooling mechanism, wherein the cooling mechanism includes:

the front right side of the top of the bottom plate is provided with a second wedge-shaped plate;

the upper side and the lower side of the front end of the first sliding module are respectively provided with a second support frame;

two charging boxes are arranged between the two second supporting frames;

two third connecting blocks are arranged on the front side of the top of the first sliding module;

the left side of the top of the first sliding module is provided with a spray head;

the air pipe is arranged between the tops of the two charging boxes and penetrates through the two third connecting blocks, and the other end of the air pipe is connected to the right side of the spray head;

the lower part of the front side of the first sliding module is provided with a frame;

the air pump is arranged on the rack, an output pipe is arranged at the top of the air pump, and the output pipe of the air pump is communicated with the two charging boxes;

the push rod is arranged at the bottom in the air pump in a sliding mode and is in contact fit with the second wedge-shaped plate;

and a third connecting spring is arranged between the push rod and the air pump.

As a preferable technical scheme of the invention, the device also comprises a sieve, and the sieve is arranged at the front side of each of the two charging boxes in a sliding manner.

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

1. people firstly place the glass lens between the two sliding clamps, then do not apply force to the sliding clamps, and under the reset action of the second reset spring, the sliding clamps move inwards to clamp the glass lens, so that the glass lens can be processed and manufactured more stably, and errors are reduced;

2. the rack drives the first wedge-shaped block to move outwards, the first wedge-shaped block drives the first sliding die and the second sliding die to move inwards, and the first sliding die and the second sliding die extrude the glass lens to form the glass lens, so that the glass lens can be automatically extruded and formed, and manual operation is reduced;

3. people rotate the rotating wheel to drive the rotating rod to rotate, the rotating rod drives the first roller wheel to rotate, the first roller wheel rotates to loosen the rope, and the sliding clamp moves inwards to clamp the glass lens under the reset action of the second reset spring, so that the manual pulling of the sliding clamp can be reduced;

4. under the normal state, the lug clamps the rotating disc, so that the rotating wheel cannot rotate along with the lug, and the rotating wheel can be controlled to rotate;

5. the push rod is extruded through the second wedge-shaped plate, so that the push rod moves to the upper side, the push rod conveys gas in the air pump, the gas is sprayed out through the spray head through the air pipe, the gas cools the glass lens, and the glass lens is convenient to perform subsequent operation.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a partial perspective sectional view of the present invention.

Fig. 3 is a schematic perspective view of the clamping mechanism of the present invention.

Fig. 4 is a schematic partial perspective view of a first placement mechanism of the present invention.

Fig. 5 is a schematic partial perspective view of a second placement mechanism of the present invention.

Fig. 6 is a third partial perspective view of the placement mechanism of the present invention.

Fig. 7 is a schematic partial perspective view of a first transmission mechanism of the present invention.

Fig. 8 is a schematic partial perspective view of a second transmission mechanism of the present invention.

Fig. 9 is a schematic view of a third partial perspective structure of the transmission mechanism of the present invention.

Fig. 10 is a schematic perspective view of the control mechanism of the present invention.

Fig. 11 is a schematic partial perspective view of a first clamping mechanism of the present invention.

Fig. 12 is a schematic view of a second partial perspective view of the jamming mechanism of the present invention.

Fig. 13 is a schematic structural view of a first partial body of the cooling mechanism of the present invention.

Fig. 14 is a schematic structural view of a second partial body of the cooling mechanism of the present invention.

Fig. 15 is a partial perspective view of the cooling mechanism of the present invention.

In the reference symbols: 1_ bottom plate, 2_ first support block, 3_ first slide module, 4_ second slide module, 5_ first fixed block, 6_ first slide mold, 7_ second slide mold, 8_ first return spring, 9_ first connecting block, 10_ clamping mechanism, 101_ support block, 102_ slide clamp, 103_ second return spring, 11_ placing mechanism, 111_ second fixed block, 112_ placing plate, 113_ first wedge block, 114_ first wedge plate, 115_ support spring, 12_ transmission mechanism, 121_ support plate, 122_ second connecting block, 123_ rack, 124_ second wedge block, 125_ first connecting spring, 126_ motor, 127_ first gear, 13_ control mechanism, 131_ rotating rod, 132_ second gear, 133_ first roller, 134_ rotating wheel, 135_ connecting rack, 136_ second roller, 137_ rope, 14_ clamping mechanism, 141_ disk, 142_ third rotating block, 143_ sliding rod, 149_ first connecting rod, 133_ first roller, 134_ rotating wheel, 135_ connecting rack, 136_ second roller, 137_ rope, 14_ clamping mechanism, 141_ disk, 142_ third rotating block, 143_ third rotating rod, 147_ second connecting block, air pump, 35_ second connecting block, 157, fourth sliding spring, third connecting block, 157, third connecting block, and fourth sliding spring, 150 _ spring, 157 connecting block, third connecting block, and fourth sliding spring mounting block, 150 _ supporting spring.

Detailed Description

The present invention is described in further detail below with reference to specific embodiments, which are given for the purpose of illustration only and are not intended to limit the scope of the invention.

Example 1

The utility model provides a glass aspheric lens manufacturing equipment of precision mould pressing, as shown in fig. 1-6, including bottom plate 1, first support frame 2, first slip module 3, second slip module 4, first fixed block 5, first slip mould 6, second slip mould 7, first reset spring 8, first connecting block 9, clamping mechanism 10 and placement mechanism 11, both sides all are equipped with first support frame 2 around the bottom plate 1 top, the slidingtype is equipped with first slip module 3 between two first support frame 2 right sides, the slidingtype is equipped with second slip module 4 between two first support frame 2 left sides, first slip module 3 all is equipped with first fixed block 5 with second slip module 4 inside, first fixed block 5 left side slidingtype on right side is equipped with first slip mould 6, first slip mould 6 and first slip module 3 sliding fit, first slip mould 6 is concave setting, left first fixed block 5 right side slidingtype is equipped with second slip mould 7, second slip mould 7 and second slip module 4 sliding fit, second slip mould 7 is protruding to be equipped with first slip module 7 and second slip module 6 and is equipped with first slip module 6 and is used for the middle slip module 7 and the bottom of first slip mechanism 6 and the bottom is used for the first slip module 9 and the bottom of first slip mechanism 11 and the bottom of the first slip module 6 and the first slip mechanism 11 and the bottom of the first slip module 9 and the bottom of the slide module 6 and the slide module is used for the first connection mechanism 7 and the first slip mechanism 9, the slide module is used for the right side to the first connection of the slide module 9, the first slide module 7, the slide module is used for the slide module 9, the slide module 7, the slide module is used for the slide module 9.

When the aspheric glass lens needs to be manufactured, firstly, people pull the clamping mechanism 10 to move outwards, then, the glass lens is placed on the placing mechanism 11, no force is applied to the clamping mechanism 10, the clamping mechanism 10 moves inwards to clamp the glass lens, then people can firstly melt the glass lens, after the glass lens is melted to a certain degree, people push the first sliding module 3 and the second sliding module 4 to move inwards along the first support frame 2, the first sliding module 3 and the second sliding module 4 drive the first sliding mold 6 and the second sliding mold 7 to move inwards, then the first sliding module 3 and the second sliding module 4 are close to each other, meanwhile, the first sliding module 3 and the second sliding module 4 are in contact with the placing mechanism 11, so that the placing mechanism 11 moves downwards to be separated from the contact with the glass lens, the placing mechanism 11 cannot block the first sliding module 3 and the second sliding module 4, the first sliding module 3 and the second sliding module 4 can process the glass lens better, people push the first sliding mold 6 and the second sliding mold 7 to move inwards, the first reset spring 8 is compressed, so that the first sliding mold 6 and the second sliding mold 7 extrude the glass lens, the first sliding mold 6 is concave and convex with the second sliding mold 7, the glass lens is extruded and formed, after the forming work is finished, people do not apply force to the first sliding mold 6 and the second sliding mold 7 any more, under the reset action of the first reset spring 8, the first sliding mold 6 and the second sliding mold 7 move outwards and reset, then people pull the first sliding module 3 and the second sliding module 4 to move outwards and reset, the first sliding module 3 is separated from the second sliding module 4, first slip module 3 and second slip module 4 break away from the contact with placement mechanism 11, and placement mechanism 11 moves with the contact of glass lens to the upside along with it, and people pull clamping mechanism 10 and move and break away from the contact with the glass lens to the outside, then take out the glass lens that the shaping is good, takes out the back, and people just no longer exert force to clamping mechanism 10, and clamping mechanism 10 moves to the inboard and resets, finally alright realize making the purpose that is the aspheric lens to the glass lens.

The clamping mechanism 10 comprises supporting blocks 101, sliding clamps 102 and second return springs 103, the supporting blocks 101 are arranged on the front side and the rear side in the middle of the top of the bottom plate 1, the sliding clamps 102 are arranged on the upper portions of the two supporting blocks 101 in a sliding mode, the sliding clamps 102 are used for clamping glass lenses, the second return springs 103 are arranged between the two sliding clamps 102 and the supporting blocks 101 on the same side, and the two second return springs 103 are wound on the sliding clamps 102 on the same side respectively.

When the glass lens needs to be clamped, people can pull the sliding clamp 102 to move outwards, the second reset spring 103 is stretched, then the glass lens is placed between the sliding clamp 102, force is not applied to the sliding clamp 102 any more, and under the reset action of the second reset spring 103, the sliding clamp 102 moves inwards to be in contact with the glass lens, so that the sliding clamp 102 clamps the glass lens, and finally, the glass lens can be clamped, and the purpose of manufacturing and forming the glass lens is facilitated.

The placing mechanism 11 comprises a second fixing block 111, a placing plate 112, first wedge-shaped blocks 113, first wedge-shaped plates 114 and supporting springs 115, the left side and the right side of the middle of the top of the bottom plate 1 are provided with the second fixing block 111, the placing plate 112 is arranged between the upper portions of the two second fixing blocks 111 in a sliding mode and used for placing glass lenses, the lower portions of the outer sides of the two second fixing blocks 111 are provided with the first wedge-shaped blocks 113 in a sliding mode, the two first wedge-shaped blocks 113 are connected with the placing plate 112, the supporting springs 115 are arranged between the two first wedge-shaped blocks 113 and the second fixing blocks 111 on the same side, the two supporting springs 115 are located inside the second fixing blocks 111 on the same side, the first sliding modules 3 and the bottoms of the second sliding modules 4 are provided with the first wedge-shaped plates 114, and the two first wedge-shaped plates 114 move inwards and are in contact with the first wedge-shaped blocks 113 on the same side.

When the glass lens needs to be placed, people pull the sliding clamp 102 to move outwards, the second return spring 103 is stretched, one then places the glass lens over the resting plate 112, and no longer applies force to the slide clamp 102, under the reset action of the second reset spring 103, the slide clamp 102 moves inwards to contact with the glass lens, therefore, the glass lenses are clamped by the sliding clamp 102, and then people push the first sliding module 3 and the second sliding module 4 to drive the first wedge-shaped plate 114 to move inwards, the first wedge-shaped plate 114 is in contact with the first wedge-shaped block 113, the first wedge-shaped block 113 moves downwards, the supporting spring 115 is compressed, the first wedge-shaped block 113 drives the placing plate 112 to move downwards to be separated from the contact with the glass lenses, at this time, the first sliding module 3 and the second sliding module 4 are close to each other, so that the placing plate 112 is not blocked by the first sliding module 3 and the second sliding module 4, then, people can manufacture the glass lens, and then people pull the first sliding module 3 and the second sliding module 4 to move outwards, the first sliding module 3 and the second sliding module 4 drive the first wedge-shaped plate 114 to move outwards, the first wedge-shaped plate 114 does not contact with the first wedge-shaped block 113, under the reset action of the supporting spring 115, the first wedge-shaped block 113 drives the placing plate 112 to move upwards for resetting, the placing plate 112 is contacted with the formed glass lens, people can pull the sliding clamp 102 to move outwards, the second reset spring 103 is stretched, the sliding clamp 102 does not clamp the glass lens, people can take off the glass lens, after taking off, people do not apply force to the sliding clamp 102 any more, under the reset action of the second reset spring 103, the slide clamp 102 moves inwards to reset, and finally, the glass lens can be placed.

Example 2

On the basis of embodiment 1, as shown in fig. 1, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14 and fig. 15, the present invention further includes a transmission mechanism 12, where the transmission mechanism 12 includes a support plate 121, a second connection block 122, a rack 123, a second wedge block 124, a first connection spring 125, a motor 126 and a first gear 127, the support plate 121 is disposed on both sides of the top of the bottom plate 1, the second connection block 122 is disposed on both sides of the middle of the top of the bottom plate 1, the rack 123 is disposed between the support plate 121 and the upper portion of the second connection block 122 on the same side in a sliding manner, the second wedge blocks 124 are disposed on both sides of the top of the two racks 123 in a sliding manner, the second wedge blocks 124 on the left side are in contact with the second sliding module 4, the second wedge blocks 124 on the right side are in contact with the first sliding module 3, the two second wedge blocks 124 move inward and are in contact with the first connection block 9 on the same side, the first wedge blocks 124 and the rack 123 are disposed with the first connection spring 125, the middle of the top of the bottom plate 1, the motor 126 is disposed on the top of the bottom plate 1, and the first gear 127.

When the first sliding module 3 and the second sliding module 4 and the first sliding mold 6 and the second sliding mold 7 need to be automatically driven to move, the person starts the motor 126, the output shaft of the motor 126 drives the first gear 127 to rotate, the first gear 127 drives the racks 123 on the two sides to move inwards, the racks 123 drive the second wedge block 124 to move inwards, the second wedge block 124 drives the first sliding module 3 and the second sliding module 4 to move inwards, the first sliding module 3 and the second sliding module 4 stop moving after contacting with each other, the racks 123 continue to drive the second wedge block 124 to move inwards, however, the second wedge block 124 is pressed by the first sliding module 3 and the second sliding module 4, the second wedge block 124 moves downwards, the first connecting spring 125 is compressed, the racks 123 drive the second wedge block 124 to move to 127 to be separated from the first sliding module 3 and the second sliding module 4, under the reset action of the first connecting spring 125, the second wedge block 124 moves upwards, the second wedge block 124 continues to move inwards and contact with the first sliding module 3 and the second sliding module 4, the rack 123 drives the first sliding module 124 to move inwards, the first sliding module 124 and the second sliding module 7 to move reversely, the first connecting spring 123, the first connecting spring 125 drives the first sliding module 124 to move, the first sliding module 124 to move reversely, the first sliding module 7 and the first sliding module 7, the first sliding module 7 to move, the first connecting spring 126 to move, the first sliding module 7, and the second sliding module 7, the first sliding module 9, the second sliding module 9, the glass is reset glass to move reversely, and the glass mold 7 reversely, and the glass mold 7, the glass mold are reset glass mold 7, and the glass mold 7 are reset glass mold, and the glass mold 7, the first connecting block 9 drives the first sliding mold 6 and the second sliding mold 7 to move outwards and reset, then the second wedge block 124 drives the first sliding module 3 and the second sliding module 4 to move outwards and reset, then the first sliding module 3 and the second sliding module 4 cannot move, the rack 123 continues to drive the second wedge block 124 to move outwards, the first sliding module 3 and the second sliding module 4 extrude the second wedge block 124, the second wedge block 124 moves downwards, the first connecting spring 125 is compressed, the rack 123 drives the second wedge block 124 to move outwards and reset, then the second wedge block 124 moves to be no longer in contact with the first sliding module 3 and the second sliding module 4, the second wedge block 124 moves upwards and resets under the reset action of the first connecting spring 125, and finally the first sliding module 3 and the second sliding module 4, the first sliding mold 6 and the second sliding mold 7 can be automatically driven to move, so that the lens glass is automatically manufactured, and the motor 126 can be closed after the operation is finished.

Still including control mechanism 13, control mechanism 13 is including bull stick 131, second gear 132, first gyro wheel 133, runner 134, link 135, second gyro wheel 136 and rope 137, the equal rotary type in both sides is equipped with bull stick 131 around 1 top left part of bottom plate, two bull stick 131 middle parts all are equipped with second gear 132, two second gear 132 mesh mutually, two bull stick 131 middle parts all are equipped with first gyro wheel 133, first gyro wheel 133 is located second gear 132 top, the bull stick 131 top of rear side is equipped with runner 134, both sides all are equipped with link 135 around 1 top left part of bottom plate, link 135 all is located bull stick 131 right side, two link 135 upper portions are equipped with two second gyro wheels 136 through the pivot rotary type, all the wraparound has the rope 137 on two first gyro wheels 133, and two ropes 137 wraparound respectively on homonymy second gyro wheel 136, the other end of two ropes 137 is connected on homonymy sliding clamp 102.

Under a normal state, the rope 137 tensions the sliding clip 102, so that the sliding clip 102 is far away from each other, the second return spring 103 is under a tension state, if a glass lens is to be clamped, a person rotates the rotating wheel 134 to drive the rear rotating rod 131 to rotate, the rear rotating rod 131 drives the rear second gear 132 to rotate, the two second gears 132 are engaged, the front second gear 132 drives the front rotating rod 131 to rotate, the two rotating rods 131 simultaneously drive the first roller 133 to rotate, the first roller 133 rotates to loosen the rope 137, then under the action of the second return spring 103, the sliding clip 102 moves inward to clamp the glass lens, meanwhile, the sliding clip 102 pulls the rope 137 to move inward, the rope 137 contacts the second roller 136 during the movement process, so that the rope 137 drives the second roller 136 to rotate, the second roller 136 rotates to assist the rope 137 to move, at this time, the glass lens is manufactured, after the work is completed, the person reversely rotates the rotating wheel 134 to drive the rear rotating rod 131 to reversely rotate, the rear rotating wheel 131 drives the rear rotating wheel 131 to rotate, the second roller 133 to assist the rope 137 to move, and then the glass lens is automatically clamped by the first return spring 132, and then the glass lens is pulled by the first return spring 132, and the glass lens 102 to rotate.

The clamping mechanism 14 is further included, the clamping mechanism 14 includes a rotating disc 141, a third fixed block 142, a sliding rod 143, a protruding block 144, a second connecting spring 145, a fixed rod 146, a sliding plate 147, a third return spring 148 and a fourth return spring 149, the rotating disc 141 is arranged at the lower portion of the rear rotating rod 131, the third fixed block 142 is arranged at the left rear side of the top of the bottom plate 1, the sliding rod 143 is slidably arranged at the top inside the third fixed block 142, the fourth return spring 149 is arranged between the sliding rod 143 and the third fixed block 142, the protruding block 144 is slidably arranged at the upper portion inside the sliding rod 143, the second connecting spring 145 is arranged between the protruding block 144 and the sliding rod 143, the protruding block 144 is tightly matched with the rotating disc 141, a plurality of through holes are formed in the rotating disc 141 and used for tightly clamping the protruding block 144, the fixed rod 146 is arranged at the left rear side of the top of the bottom plate 1, the fixed rod 146 is located at the right side of the third fixed block 142, the sliding plate 146 is slidably arranged at the upper portion of the fixed rod 146, the sliding plate 147, the third return spring 148 is arranged between the sliding plate 147 and the fixed rod 146, and the sliding plate 147 is connected with the sliding rod 143.

Under the normal state, the protrusion 144 clamps the rotating disc 141 to make the rotating rod 131 unable to rotate, if clamping the glass lens, one first places the glass lens on the placing plate 112, then pulls the sliding plate 147 to move downward along the fixing rod 146, the third return spring 148 is stretched, the sliding plate 147 drives the sliding rod 143 to move downward along the third fixing block 142, the fourth return spring 149 is compressed, the sliding rod 143 drives the protrusion 144 to move downward, the protrusion 144 is no longer in contact with the rotating disc 141, at this time, one can rotate the rotating wheel 134 to drive the rotating rod 131 to rotate, the rotating rod 131 drives the first roller 133 to rotate, the rope 137 is loosened, the initial state of the second return spring 103 is in the stretching state, under the reset action of the second return spring 103, the sliding clamp 102 pulls the rope 137 to move inward, the sliding clamp 102 clamps the glass lens, and after finishing the processing of the glass lens, the rotating wheel 134 is rotated reversely by people to drive the rotating rod 131 to rotate reversely, the rotating rod 131 drives the first roller 133 to rotate reversely, the first roller 133 rotates reversely to tighten the rope 137, so that the rope 137 pulls the sliding clamp 102 to move outwards, the second return spring 103 is stretched, the sliding clamp 102 no longer clamps the glass lens, then people no longer apply force to the sliding plate 147, under the reset action of the third return spring 148, the sliding plate 147 moves and resets upwards, the sliding plate 147 drives the sliding rod 143 to move and reset upwards, the fourth return spring 149 resets therewith, the third return spring 148 plays a role of buffering, the sliding rod 143 drives the lug 144 to move upwards to contact with the rotating disc 141, the rotating disc 141 extrudes the lug 144, so that the lug 144 moves downwards, the second connecting spring 145 is compressed, then people can rotate the rotating wheel 134 to drive the rotating rod 131 and the rotating disc 141 to rotate slightly, make lug 144 can correspond with rolling disc 141 through-hole, under the reset action of second connecting spring 145, lug 144 moves to the upshifting and resets to lug 144 carries out the chucking to rolling disc 141, finally alright realize chucking to rolling disc 141, make runner 134 unable thereupon rotate, and then control runner 134 rotates, the purpose of the tight glass lens of clamp of can stabilizing more.

The gas-liquid separator further comprises a cooling mechanism 15, the cooling mechanism 15 comprises a second wedge-shaped plate 151, a second support frame 152, charging boxes 153, third connecting blocks 154, a spray head 155, a gas pipe 156, a frame 157, an air pump 158, a push rod 159 and a third connecting spring 1510, the second wedge-shaped plate 151 is arranged on the front right side of the top of the bottom plate 1, the second support frame 152 is arranged on the upper side and the lower side of the front end of the first sliding module 3, two charging boxes 153 are arranged between the two second support frames 152 and used for storing gas, screens are arranged on the front sides of the two charging boxes 153 in a sliding mode and used for conveying the gas, the two third connecting blocks 154 are arranged on the front side of the top of the first sliding module 3, a spray head 155 is arranged on the left side of the top of the first sliding module 3, an air pipe 156 is arranged between the tops of the two charging boxes 153, the air pipe 156 penetrates through the two third connecting blocks 154, the other end of the air pipe 156 is connected to the right side of the spray head 155, a rack 157 is arranged on the lower portion of the front side of the first sliding module 3, an air pump 158 is mounted on the rack 157, an output pipe is arranged on the top of the air pump 158, a push rod 159 is slidably arranged at the bottom in the air pump 158, the push rod 159 is in contact fit with the second wedge-shaped plate 151, a third connecting spring 1510 is arranged between the push rod 159 and the air pump 158, and the output pipe of the air pump 158 is communicated with the two charging boxes 153.

Because the temperature of the glass lens which is just processed is higher, the glass lens needs to be cooled to be processed subsequently, at the moment, people can firstly pull the sieve to move towards the front side to be separated from the contact with the charging box 153, then, the gas is supplied into the charging box 153 through the external connection pipe, and after the gas is supplied, the sieve is installed back into the charging box 153 by the person standing on the ground, when the first sliding module 3 moves inward, the first sliding module 3 drives the frame 157 and the second supporting frame 152 to move inward, the frame 157 drives the air pump 158 and the push rod 159 to move inward, the push rod 159 moves inward to be separated from the second wedge plate 151, the third connecting spring 1510 is in a compressed state in an initial state, under the reset action of the third connecting spring 1510, the push rod 159 moves to the lower side for reset, so that the push rod 159 sucks the gas in the charging box 153, so that the gas is delivered into the gas pump 158, after the glass lens is processed, the first sliding module 3 drives the frame 157 and the second supporting frame 152 to move outward, the frame 157 drives the air pump 158 and the push rod 159 to move outward, the push rod 159 moves to contact with the second wedge plate 151, the second wedge plate 151 extrudes the push rod 159, so that the push rod 159 moves upward, the third connecting spring 1510 is compressed, the push rod 159 presses the gas in the gas pump 158, the gas is delivered into the charging box 153 along the output pipe of the gas pump 158, thereby gaseous impulsive force of gas delivery carries out the punching press to the gas in the charging box 153 for the gas in the charging box 153 is spout through shower nozzle 155 along trachea 156, and shower nozzle 155 is gas-blast on the glass lens, and gas cools down the glass lens, finally alright realize cooling down the glass lens that has just been processed, makes the glass lens can carry out the purpose of subsequent processing.

The embodiments described above are provided to enable persons skilled in the art to make or use the invention and such modifications or variations may be made to the embodiments described above by persons skilled in the art without departing from the inventive concept of the present invention, and therefore the scope of protection of the present invention is not limited by the embodiments described above but should be accorded the widest scope consistent with the innovative features set forth in the claims.

Claims (5)

1. The utility model provides a glass aspherical mirror lens manufacturing equipment of precision mould pressing which characterized in that includes: the front side and the rear side of the top of the bottom plate (1) are respectively provided with a first support frame (2);

the first sliding module (3) is arranged between the right sides of the two first supporting frames (2) in a sliding manner;

the second sliding module (4) is arranged between the left sides of the two first supporting frames (2) in a sliding manner;

the first fixing block (5) is arranged inside each of the first sliding module (3) and the second sliding module (4);

the first sliding die (6) is arranged on the left side of the first fixing block (5) on the right side in a sliding manner, and the first sliding die (6) is in sliding fit with the first sliding module (3);

the second sliding mold (7) is arranged on the right side of the first fixed block (5) on the left side in a sliding mode, and the second sliding mold (7) is in sliding fit with the second sliding module (4);

a first reset spring (8) is arranged between the first sliding die (6) and the first fixed block (5) on the right side, and a first reset spring (8) is arranged between the second sliding die (7) and the first fixed block (5) on the left side;

the bottom parts of the first sliding die (6) and the second sliding die (7) are respectively provided with a first connecting block (9), the first connecting block (9) on the right side is in sliding fit with the first sliding module (3), and the first connecting block (9) on the left side is in sliding fit with the second sliding module (4);

the middle of the top of the bottom plate (1) is provided with a clamping mechanism (10) for clamping the lens;

the device comprises a placing mechanism (11), wherein the placing mechanism (11) is arranged in the middle of the top of the bottom plate (1), and the placing mechanism (11) is matched with a first sliding die (6) and a second sliding die (7);

the clamping mechanism (10) comprises:

the front side and the rear side of the middle of the top of the bottom plate (1) are respectively provided with a supporting block (101);

the upper parts of the two supporting blocks (101) are both provided with sliding clamps (102) in a sliding manner;

the second reset springs (103) are arranged between the two sliding clamps (102) and the supporting block (101) on the same side, and the two second reset springs (103) are respectively wound on the sliding clamps (102) on the same side;

the placement mechanism (11) includes:

the left side and the right side of the middle of the top of the bottom plate (1) are respectively provided with a second fixed block (111);

the placing plate (112) is arranged between the upper parts of the two second fixing blocks (111) in a sliding manner;

the lower parts of the outer sides of the two second fixing blocks (111) are both provided with a first wedge-shaped block (113) in a sliding manner, and the two first wedge-shaped blocks (113) are both connected with the placing plate (112);

the supporting springs (115) are arranged between the two first wedge-shaped blocks (113) and the second fixing block (111) on the same side, and the two supporting springs (115) are located inside the second fixing block (111) on the same side;

the bottoms of the first sliding module (3) and the second sliding module (4) are respectively provided with a first wedge-shaped plate (114), and the two first wedge-shaped plates (114) move inwards and are respectively contacted with the first wedge-shaped blocks (113) on the same side;

still including drive mechanism (12), drive mechanism (12) include:

the left side and the right side of the top of the bottom plate (1) are provided with supporting plates (121);

the left side and the right side of the middle of the top of the bottom plate (1) are both provided with the second connecting blocks (122);

the racks (123) are arranged between the supporting plate (121) and the upper part of the second connecting block (122) on the same side in a sliding manner;

the tops of the outer sides of the two racks (123) are both provided with a second wedge block (124) in a sliding mode, the second wedge block (124) on the left side is in contact fit with the second sliding module (4), the second wedge block (124) on the right side is in contact fit with the first sliding module (3), and the two second wedge blocks (124) move inwards and are both in contact with the first connecting block (9) on the same side;

the first connecting springs (125) are arranged between the two second wedge blocks (124) and the rack (123) on the same side;

the motor (126) is installed in the middle of the top of the bottom plate (1);

the first gear (127) is arranged on an output shaft of the motor (126), and the first gear (127) is meshed with the two racks (123).

2. The apparatus for manufacturing a precision press-molded glass aspherical lens as defined in claim 1, wherein: still including control mechanism (13), control mechanism (13) includes:

the front side and the rear side of the left end of the top of the bottom plate (1) are respectively and rotatably provided with a rotating rod (131);

the middle parts of the two rotating rods (131) are provided with second gears (132), and the two second gears (132) are meshed;

the middle parts of the two rotating rods (131) are respectively provided with a first roller (133), and the first rollers (133) are positioned above the second gear (132);

the top of the rotating rod (131) at the rear side is provided with a rotating wheel (134);

the front side and the rear side of the left end of the top of the bottom plate (1) are provided with connecting frames (135);

the upper parts of the two connecting frames (135) are rotatably provided with two second rollers (136) through rotating shafts;

the ropes (137) are wound on the two first rollers (133), the two ropes (137) are wound on the second roller (136) on the same side respectively, and the other ends of the two ropes (137) are connected to the sliding clamp (102) on the same side.

3. The apparatus for manufacturing a precision press-molded glass aspherical lens as defined in claim 2, wherein: still including blocking mechanism (14), block mechanism (14) and include:

a rotating disc (141), wherein the lower part of the rear rotating rod (131) is provided with the rotating disc (141);

the left rear side of the top of the bottom plate (1) is provided with a third fixed block (142);

the sliding rod (143) is arranged at the top in the third fixing block (142) in a sliding manner;

a fourth return spring (149), wherein the fourth return spring (149) is arranged between the sliding rod (143) and the third fixed block (142);

the upper part in the sliding rod (143) is provided with a convex block (144) in a sliding way, and the convex block (144) is tightly matched with the rotating disc (141) in a clamping way;

a second connecting spring (145) is arranged between the convex block (144) and the sliding rod (143);

the fixing rod (146) is arranged on the left rear side of the top of the bottom plate (1), and the fixing rod (146) is located on the right side of the third fixing block (142);

a sliding plate (147), wherein the sliding plate (147) is arranged on the upper part of the fixed rod (146) in a sliding way;

and a third return spring (148) is arranged between the sliding plate (147) and the fixed rod (146), and the sliding plate (147) is connected with the sliding rod (143).

4. The apparatus for manufacturing a precision press-molded glass aspherical lens as defined in claim 3, wherein: still including cooling mechanism (15), cooling mechanism (15) include:

the front right side of the top of the bottom plate (1) is provided with a second wedge-shaped plate (151);

the upper side and the lower side of the front end of the first sliding module (3) are respectively provided with a second supporting frame (152);

two charging boxes (153) are arranged between the two second supporting frames (152);

the front side of the top of the first sliding module (3) is provided with two third connecting blocks (154);

the sprayer (155), the left side of the top of the first sliding module (3) is provided with the sprayer (155);

the air pipe (156) is arranged between the tops of the two charging boxes (153), the air pipe (156) penetrates through the two third connecting blocks (154), and the other end of the air pipe (156) is connected to the right side of the spray head (155);

the lower part of the front side of the first sliding module (3) is provided with a frame (157);

the air pump (158) is installed on the rack (157), an output pipe is arranged at the top of the air pump (158), and the output pipe of the air pump (158) is communicated with the two charging boxes (153);

the push rod (159), the inner bottom of the air pump (158) is provided with the push rod (159) in a sliding way, and the push rod (159) is in contact fit with the second wedge-shaped plate (151);

and a third connecting spring (1510) is arranged between the push rod (159) and the air pump (158).

5. The apparatus for manufacturing a precision press-molded glass aspherical lens as defined in claim 4, wherein: the screen feeder also comprises a screen, and the screens are arranged on the front sides of the two charging boxes (153) in a sliding manner.

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