CN212526723U - Automatic assembling machine for primary lens of 5G optical module - Google Patents

Abstract

The utility model relates to an automatic assembling machine for a primary lens of a 5G optical module, which comprises a base station, wherein the upper surface of the base station is provided with a guide convex part, a clamp is arranged on the convex part, and a lens assembling jig is arranged on the clamp; the left part and the right part symmetry of base station are provided with the support column, two install the crossbeam between the support column, and the crossbeam front surface is provided with lifting unit, lifting unit include with C type slider fixed connection's installation shell, the front surface mounting of installation shell has the lifter plate, the lens is installed to the left lower part of lifter plate front surface and is drawn the subassembly, the subassembly is glued to the right lower part of lifter plate front surface installs the lens. The cooperation of the conveying belts enables the lens suction assembly and the lens dispensing assembly to rapidly and accurately move to a lens suction position and a lens dispensing position; the lens sucking component is used for sucking and putting down the lens; the lens dispensing component drips the glue on the lens; the UV irradiation lamp can accelerate the solidification of the glue; the two lenses are quickly and accurately bonded.

Description

Automatic assembling machine for primary lens of 5G optical module

Technical Field

The utility model relates to a 5G optical module makes technical field, especially a 5G optical module primary lens automatic assembly machine.

Background

With the development of the mobile internet, more and more devices are connected to the mobile network, new services and applications are in endless, and the capacity of the mobile communication network is expected to increase 1000 times over the current network capacity. The explosion of mobile data traffic will present a serious challenge to the network. Therefore, 5G wireless communication technology comes to the end, the market of the 5G communication field is large, but the price of 400G/800G transceiving components and modules applied to a global large-scale data center is high, and the process still needs to be broken through. The receiving and transmitting assembly and the module are photoelectronic devices for photoelectric and electro-optical conversion, and are composed of photoelectronic devices, functional circuits, optical interfaces and the like, wherein the photoelectronic devices comprise a transmitting part and a receiving part. The sending end of the optical module converts the electric signal into an optical signal, and the receiving end converts the optical signal into the electric signal.

Before the 5G function is realized, the basic technology of the optical module, particularly the bonding of two lenses, needs to be completed.

SUMMERY OF THE UTILITY MODEL

In order to solve the above problems, the present invention provides an automatic assembling machine for 5G optical module primary lenses, which realizes the automatic glue-dispensing and adhesion of two optical lenses.

The embodiment of the utility model provides an in adopt following scheme to realize: the automatic assembling machine for the primary lens of the 5G optical module comprises a base station, wherein first synchronous belt wheels are arranged at the front part and the rear part in the base station, and first synchronous belts are arranged on the two first synchronous belt wheels; the upper surface of the base station is provided with a guide convex part, the left side and the right side of the convex part are both provided with through grooves, the convex part is provided with a clamp, the left side and the right side of the clamp are symmetrically bent inwards and respectively extend into the through grooves on the left side and the right side of the convex part, and the clamp is provided with a lens assembling jig; a first fixing block is arranged on the first synchronous belt and connected with the side edge of the clamp; the left part and the right part of the base station are symmetrically provided with support columns, a cross beam is arranged between the two support columns, second synchronous belt pulleys are arranged on the left part and the right part in the cross beam, second synchronous belts are arranged on the two second synchronous belt pulleys, second sliding grooves are symmetrically formed in the upper part and the lower part of the front surface of the cross beam, a C-shaped sliding block is fixed on the front surface of each second synchronous belt, the upper side edge and the lower side edge of each C-shaped sliding block penetrate through the second sliding grooves in the upper part and the lower part of the front surface of the cross beam respectively and are connected with lifting assemblies, each lifting assembly comprises an installation shell fixedly connected with the C-shaped sliding block, a lifting plate is arranged on the front surface of the installation shell, a lens absorbing assembly is arranged on the left lower part of the front surface of the; the first synchronous belt wheel and the second synchronous belt wheel are respectively driven by a first driving motor and a second driving motor.

In an embodiment of the present invention, third synchronous pulleys are installed at the top and the bottom of the installation shell, third synchronous belts are installed on two third synchronous pulleys, first chutes are symmetrically formed in the front portions of the left and right sides of the installation shell, limit sliders are symmetrically installed on the left and right sides of the rear surface of the lifting plate, the heads of the two limit sliders penetrate into the first chutes on the left and right sides respectively, one of the limit sliders is connected with a fixed connection block, the fixed connection block is fixed on one side surface of the third synchronous belt to realize the vertical movement of the lifting plate, and the third synchronous pulleys are driven by a third driving motor;

the lens sucking assembly comprises a fixing plate fixed at the lower part of the front surface of the lifting plate, a telescopic cylinder is arranged in the fixed plate, a push rod of the telescopic cylinder penetrates out of the lower surface of the fixed plate, the tail end of the push rod of the telescopic cylinder is connected with a push plate, the front surface of the fixed plate is provided with a vertical T-shaped groove, the front surface of the fixed plate is provided with an inverted T-shaped moving plate, the lower part of the inverted T-shaped moving plate is connected with the push plate, a vertical T-shaped sliding block is arranged in the middle of the rear surface of the inverted T-shaped moving plate and is matched with the T-shaped groove, a first through hole penetrating through the inverted T-shaped moving plate is formed in the middle of the inside of the inverted T-shaped moving plate, the lower end of the first through hole is provided with a suction head, the upper end of the first through hole is connected with a first air supply pipe, and the first air supply pipe is connected with a vacuum pump;

the subassembly is glued to lens point includes a point and glues the cylinder, cylinder mounting bracket, the cylinder mounting bracket is fixed the right part of the front surface of lifter plate, a point is glued the cylinder and is installed on the cylinder mounting bracket, and the second air supply pipe is connected to the upper end of a point syringe, the head of a point syringe is installed and is had the syringe needle, and the second air supply pipe is connected with air compressor.

In one embodiment of the present invention, a plurality of positioning screws are provided at equal intervals on the lower right portion of the lifting plate, the syringe mounting bracket is C-shaped, a mounting groove is separately provided on the vertical portion of the syringe mounting bracket, and a fixing bolt is screwed into the positioning screw through the mounting groove; the horizontal parts of the top and the bottom of the needle cylinder mounting frame are respectively provided with a second through hole and a third through hole; an adjusting bolt is installed on the side wall of the second through hole, the dispensing needle cylinder penetrates through the second through hole, and the head of the dispensing needle cylinder penetrates out of the third through hole; and a UV (ultraviolet) irradiation lamp is arranged on the lower surface of the needle cylinder mounting frame.

The utility model relates to an embodiment, left part and right part symmetry installation in the fixed plate telescopic cylinder, two telescopic cylinder's push rod is connected respectively the left part and the right part of push pedal upper surface, the horizontal part's of the type of falling T movable plate rear surface with the front surface of push pedal is fixed.

The utility model relates to an embodiment, lens equipment tool includes the basal disc, equidistant set up screw hole along the bilateral symmetry axis of basal disc on the basal disc, the upper surface array of basal disc left part is provided with the lens standing groove, the upper surface symmetry of basal disc right part sets up equal quantity lens standing groove.

The utility model has the advantages that: the utility model provides a 5G optical module primary lens automatic assembly machine, the cooperation of a first conveyor belt, a second conveyor belt and a third conveyor belt enables a lens absorbing component and a lens dispensing component to rapidly and accurately move to a position for absorbing lenses and a position for dispensing; the first air supply pipe and the vacuum pump are matched to suck lenses and put down the lenses; the second air supply pipe supplies air to the needle cylinder, and the glue used for dispensing is pressed out and dripped on the lens; placing a lens on the lens with the glue, and arranging a UV (ultraviolet) irradiation lamp to irradiate the glue on the lens, wherein the glue on the lens can accelerate the solidification of the glue; the two lenses are quickly and accurately bonded together.

Drawings

Fig. 1 is a front view of a 5G optical module primary lens automated assembly machine.

Fig. 2 is a view from a-a of fig. 1.

Fig. 3 is a side view of a 5G optical module primary lens automated assembly machine.

Fig. 4 is an installation diagram of the lifting assembly, the lens sucking assembly and the lens dispensing assembly.

Fig. 5 is a schematic view of the lens dispensing assembly mounted on the lifting assembly.

Fig. 6 is a schematic structural view of a lens assembly jig.

Detailed Description

The present invention will be further explained with reference to the accompanying drawings.

Referring to fig. 1 to 6, the present invention provides an automatic assembling machine for 5G optical module primary lenses, which includes a base 101, wherein a first synchronous pulley 105 is installed at the front and the rear of the base 101, and a first synchronous belt 106 is installed on the two first synchronous pulleys 105; a guide convex part 102 is arranged on the upper surface of the base platform 101, through grooves 104 are formed in the left side and the right side of the convex part 102, a clamp 103 is installed on the convex part 102, the left side and the right side of the clamp 103 are symmetrically bent inwards and respectively extend into the through grooves 104 in the left side and the right side of the convex part 102, and a lens assembling jig 401 is installed on the clamp 103; a first fixing block 107 is arranged on the first synchronous belt 106, and the first fixing block 107 is connected with the side edge of the clamp 103; the left part and the right part of the base platform 101 are symmetrically provided with support columns 108, a cross beam 109 is installed between the two support columns 108, the left part and the right part in the cross beam 109 are both provided with second synchronous pulleys 501, the two second synchronous pulleys 501 are provided with second synchronous belts 502, second sliding grooves are symmetrically formed in the upper part and the lower part of the front surface of the cross beam 109, the front surface of each second synchronous belt 502 is fixed with a C-shaped sliding block 503, the upper side and the lower side of the C-shaped sliding block 503 penetrate through the second sliding grooves in the upper part and the lower part of the front surface of the cross beam 109 respectively and are connected with a lifting assembly, the lifting assembly comprises an installation shell 201 fixedly connected with the C-shaped sliding block 503, the front surface of the installation shell 201 is provided with a lifting plate 202, the left lower part of the front surface of the lifting plate 202 is provided with a lens suction assembly; the first synchronous pulley 105 and the second synchronous pulley 501 are respectively driven by a first driving motor and a second driving motor; the front-back movement of the clamp and the left-right movement of the lifting assembly are realized, so that the lens sucking assembly can move to the appointed position for sucking the lens, and the lens assembling jig moves the appointed position for sucking the lens.

Referring to fig. 1 to 5, in an embodiment of the present invention, third synchronous pulleys 210 are installed at the top and the bottom of the installation shell 201, third synchronous belts 212 are installed on the two third synchronous pulleys 210, first chutes are symmetrically formed in the front portions of the left and right sides of the installation shell 201, limit sliders 213 are symmetrically installed at the left and right sides of the rear surface of the lifting plate 202, the heads of the two limit sliders 213 penetrate into the first chutes at the left and right sides, respectively, one of the limit sliders 213 is connected to a fixed connection block 211, the fixed connection block 211 is fixed on one side surface of the third synchronous belt 212 to realize vertical movement of the lifting plate 202, and the third synchronous pulleys 210 are driven by a third driving motor;

the lens sucking assembly comprises a fixed plate 203, the fixed plate 203 is fixed on the lower portion of the front surface of the lifting plate 202, a telescopic cylinder 216 is installed in the fixed plate 203, a push rod of the telescopic cylinder 216 penetrates out of the lower surface of the fixed plate 203, a push plate 217 is connected to the tail end of the push rod of the telescopic cylinder 216, a vertical T-shaped groove is formed in the front surface of the fixed plate 203, an inverted T-shaped moving plate 218 is installed on the front surface of the fixed plate 203, the lower portion of the inverted T-shaped moving plate 218 is connected with the push plate 217, a vertical T-shaped sliding block is arranged in the middle of the rear surface of the inverted T-shaped moving plate 218, and the T-shaped sliding block is matched with the T-shaped groove and plays a role in guiding for; a first through hole penetrating through the inverted T-shaped moving plate 218 is formed in the middle of the inside of the inverted T-shaped moving plate 218, a suction head 206 is installed at the lower end of the first through hole, a first air supply pipe 208 is connected to the upper end of the first through hole, and a vacuum pump (not shown) is connected to the first air supply pipe 208; suction for the lens;

the lens dispensing assembly comprises a dispensing syringe 205 and a syringe mounting frame 204, the syringe mounting frame 204 is fixed at the right part of the front surface of the lifting plate 202, the dispensing syringe 205 is mounted on the syringe mounting frame 204, the upper end of the dispensing syringe 205 is connected with a second air supply pipe 209, the head of the dispensing syringe 205 is provided with a needle 207, and the second air supply pipe 209 is connected with an air compressor (not shown) for controlling the extrusion of glue;

the utility model discloses what claim require is concrete mechanical structure, as to how to control vacuum pump, air compressor, first driving motor, second driving motor, third driving motor and be prior art and do not make the protection requirement.

Referring to fig. 1 to 5, in an embodiment of the present invention, a plurality of positioning screw holes (not shown) are disposed at equal intervals on a lower right portion of the lifting plate 202, the syringe mounting bracket 204 is C-shaped, a mounting groove (not shown) is separately disposed on a vertical portion of the syringe mounting bracket 204, a fixing bolt (not shown) passes through the mounting groove and is screwed into the positioning screw holes, so that a mounting height of the lens dispensing assembly on the lifting plate can be adjusted; the horizontal parts of the top and the bottom of the needle cylinder mounting frame 204 are respectively provided with a second through hole and a third through hole; an adjusting bolt 214 is mounted on the side wall of the second through hole and used for adjusting the mounting height of the dispensing needle cylinder, the dispensing needle cylinder 205 penetrates through the second through hole, and the head of the dispensing needle cylinder 205 penetrates out of the third through hole; the lower surface of the syringe mounting bracket 204 is provided with a UV irradiation lamp 215 for accelerating the solidification of the glue.

Referring to fig. 1 and 4, in an embodiment of the present invention, the telescopic cylinders 216 are symmetrically installed at the left portion and the right portion of the fixing plate 203, push rods of the two telescopic cylinders 216 are respectively connected to the left portion and the right portion of the upper surface of the push plate 217, and the rear surface of the horizontal portion of the inverted T-shaped moving plate 218 is fixed to the front surface of the push plate 217 to drive the inverted T-shaped moving plate to vertically move.

Referring to fig. 6, in an embodiment of the present invention, the lens assembling jig 401 includes a base plate, threaded holes 403 are formed in the base plate at equal intervals along the bilateral symmetry axis of the base plate, lens placing grooves 402 are formed in the upper surface array of the left portion of the base plate, and the lens placing grooves are arranged in the upper surface symmetry of the right portion of the base plate in an equal number, so that the lens sucking efficiency and the lens dispensing assembling efficiency are improved reasonably.

Referring to fig. 1 to 5, in an embodiment of the present invention, an air supply box 6 is installed on an outer side surface of one of the support columns, a vacuum pump and an air compressor are installed in the air supply box, a drag chain 504 is installed on an upper surface of the cross beam 109, one end of the drag chain is fixed on the cross beam, the other end of the drag chain is fixed on the top of the installation shell 201, and an air pipe for supplying air to the telescopic cylinder, the first air supply pipe 208 and the second air supply pipe 209 all pass through the drag chain; the top of the mounting shell is protruded backwards, the lower surface of the protruding part is provided with a pulley, and the surface of the pulley is in contact with the upper surface of the cross beam.

The utility model discloses the theory of operation below has:

placing a lens to be subjected to glue dispensing in a lens placing groove at the left part of a lens assembling jig, fixing the lens assembling jig on a clamp, rotating a first synchronous belt, conveying the lens assembling jig to the lower part of a cross beam, driving a lifting assembly to move left and right by the motion of a second synchronous belt, aligning a suction head of a suction assembly to a single lens to be sucked, driving a lifting plate to move downwards by the motion of a third synchronous belt, pushing out by a telescopic cylinder of the suction assembly to drive an inverted T-shaped moving plate to move downwards to be close to the lens to be subjected to glue dispensing, and sucking the lens by the suction head; retracting the telescopic cylinder to enable the suction head to drive the lens to move upwards, driving the mounting shell to move rightwards synchronously, enabling the suction head to be located above the lens placing groove at the right part of the lens assembling jig, pushing out the lens absorbed by the suction head to be close to the lens placing groove by the telescopic cylinder, and enabling the lens to fall into the lens placing groove by the first air supply pipe through air supply; the telescopic cylinder retracts, the second synchronous belt moves to drive the needle head to move to the top of the lens, and the third synchronous belt moves to press the needle head to a specified position; the second air supply pipe supplies air to extrude and drip the glue in the needle cylinder on the lens; the third synchronous belt rotates reversely to drive the needle head to be far away from the lens, the second synchronous belt moves reversely to enable the suction head to move to the position where the lens to be glued is placed, the third synchronous belt moves forwards, the telescopic cylinder is pushed out, and the suction head sucks the lens to be glued; the push rod of the telescopic cylinder retracts, the second synchronous belt drives the mounting shell to move rightwards to convey the lens to be subjected to glue dispensing to the top of the original lens subjected to glue dispensing, the push rod of the telescopic cylinder pushes the lens sucked by the first air supply pipe out to fall onto a glue dispensing position, then the push rod of the telescopic cylinder retracts, the second synchronous belt drives the needle cylinder to move to the position above the glue dispensing lens, the UV irradiation lamp is started to irradiate the lens subjected to glue dispensing, and solidification of glue is accelerated; the lens is sucked in sequence by the circulation (the first row of the lens placing groove on the left half part of the lens assembling jig starts to be taken from left to right, the second row can be taken only after the first row is taken, the first synchronous belt on the base station drives the clamp to move so as to drive the lens assembling jig to move, the second row of the lens placing groove moves to the position below the movement track of the lens sucking component and the lens dispensing component, the dispensing sequence is also the same, the lens can be placed in the second row only after the first row of the lens placing groove on the right half part of the lens assembling jig is filled with the lens which is subjected to dispensing and bonding, and the first driving motor drives the first synchronous belt to move so as to keep the lens placing groove on the lens assembling jig in the position which can accurately suck or dispense the lens all the time).

The above description is only for the preferred embodiment of the present invention, and should not be interpreted as limiting the scope of the present invention, which is intended to cover all the equivalent changes and modifications made in accordance with the claims of the present invention.

Claims (5)

1. The utility model provides a 5G optical module primary lens automatic assembly machine which characterized in that: the device comprises a base station, wherein first synchronous belt wheels are arranged at the front part and the rear part in the base station, and first synchronous belts are arranged on the two first synchronous belt wheels; the upper surface of the base station is provided with a guide convex part, the left side and the right side of the convex part are both provided with through grooves, the convex part is provided with a clamp, the left side and the right side of the clamp are symmetrically bent inwards and respectively extend into the through grooves on the left side and the right side of the convex part, and the clamp is provided with a lens assembling jig; a first fixing block is arranged on the first synchronous belt and connected with the side edge of the clamp; the left part and the right part of the base station are symmetrically provided with support columns, a cross beam is arranged between the two support columns, second synchronous belt pulleys are arranged on the left part and the right part in the cross beam, second synchronous belts are arranged on the two second synchronous belt pulleys, second sliding grooves are symmetrically formed in the upper part and the lower part of the front surface of the cross beam, a C-shaped sliding block is fixed on the front surface of each second synchronous belt, the upper side edge and the lower side edge of each C-shaped sliding block penetrate through the second sliding grooves in the upper part and the lower part of the front surface of the cross beam respectively and are connected with lifting assemblies, each lifting assembly comprises an installation shell fixedly connected with the C-shaped sliding block, a lifting plate is arranged on the front surface of the installation shell, a lens absorbing assembly is arranged on the left lower part of the front surface of the; the first synchronous belt wheel and the second synchronous belt wheel are respectively driven by a first driving motor and a second driving motor.

2. The 5G optical module primary lens automatic assembly machine of claim 1, wherein: third synchronous belt wheels are mounted at the top and the bottom of the mounting shell, third synchronous belts are mounted on the two third synchronous belt wheels, first sliding grooves are symmetrically formed in the front portions of the left side edge and the right side edge of the mounting shell, limiting sliding blocks are symmetrically mounted on the left side and the right side of the rear surface of the lifting plate, the heads of the two limiting sliding blocks penetrate into the first sliding grooves on the left side and the right side respectively, one limiting sliding block is connected with a fixed connecting block, the fixed connecting block is fixed on one side face of each third synchronous belt to achieve vertical movement of the lifting plate, and the third synchronous belt wheels are driven by a third driving motor;

the lens sucking assembly comprises a fixing plate fixed at the lower part of the front surface of the lifting plate, a telescopic cylinder is arranged in the fixed plate, a push rod of the telescopic cylinder penetrates out of the lower surface of the fixed plate, the tail end of the push rod of the telescopic cylinder is connected with a push plate, the front surface of the fixed plate is provided with a vertical T-shaped groove, the front surface of the fixed plate is provided with an inverted T-shaped moving plate, the lower part of the inverted T-shaped moving plate is connected with the push plate, a vertical T-shaped sliding block is arranged in the middle of the rear surface of the inverted T-shaped moving plate and is matched with the T-shaped groove, a first through hole penetrating through the inverted T-shaped moving plate is formed in the middle of the inside of the inverted T-shaped moving plate, the lower end of the first through hole is provided with a suction head, the upper end of the first through hole is connected with a first air supply pipe, and the first air supply pipe is connected with a vacuum pump;

the subassembly is glued to lens point includes a point and glues the cylinder, cylinder mounting bracket, the cylinder mounting bracket is fixed the right part of the front surface of lifter plate, a point is glued the cylinder and is installed on the cylinder mounting bracket, and the second air supply pipe is connected to the upper end of a point syringe, the head of a point syringe is installed and is had the syringe needle, and the second air supply pipe is connected with air compressor.

3. The 5G optical module primary lens automatic assembly machine of claim 2, wherein: a plurality of positioning screw holes are formed in the right lower part of the lifting plate at equal intervals, the needle cylinder mounting frame is in a C-shaped frame shape, a mounting groove is formed in the vertical part of the needle cylinder mounting frame, and a fixing bolt penetrates through the mounting groove and is screwed into the positioning screw holes; the horizontal parts of the top and the bottom of the needle cylinder mounting frame are respectively provided with a second through hole and a third through hole; an adjusting bolt is installed on the side wall of the second through hole, the dispensing needle cylinder penetrates through the second through hole, and the head of the dispensing needle cylinder penetrates out of the third through hole; and a UV (ultraviolet) irradiation lamp is arranged on the lower surface of the needle cylinder mounting frame.

4. The 5G optical module primary lens automatic assembly machine of claim 2, wherein: the left part and the right part in the fixed plate are symmetrically provided with the telescopic cylinders, push rods of the two telescopic cylinders are respectively connected with the left part and the right part of the upper surface of the push plate, and the rear surface of the horizontal part of the inverted T-shaped moving plate is fixed with the front surface of the push plate.

5. The 5G optical module primary lens automatic assembly machine of claim 1, wherein: the lens equipment tool includes the base plate, the bilateral symmetry axis equidistant set up screw hole along the base plate on the base plate, the upper surface array of base plate left part is provided with the lens standing groove, the upper surface symmetry of base plate right part sets up equal quantity lens standing groove.

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