CN104238036B - Bridge type ceramic insertion core direction adjustment device - Google Patents

Abstract

The invention discloses a kind of bridge type ceramic insertion core direction adjustment device, comprise base plate, feeding mechanism, driving mechanism, draw point, expeller, splicing block, tuning block; Base plate is fixed expeller, splicing block, tuning block; Expeller end face is with pusher chute, with vertical splicing passage in the middle of splicing block, splicing passage upper port width is 1/2 to 2/3 of ceramic insertion core length, the end face of tuning block is with the downward-sloping tip chute of left end, pusher chute right output port, splicing passage upper port, tip chute left port three connect, ceramic insertion core can slide in pusher chute, tip chute, and can fall into splicing passage; Feeding mechanism conveying ceramic insertion core is in the pusher chute of expeller; The right-hand member of draw point is with the tip coordinated with ceramic insertion core hydraucone; Driving mechanism fixes draw point, moves back and forth about driving draw point, when draw point moves to right, the ceramic insertion core that draw point promotes in pusher chute slips into tip chute to the right or falls into splicing passage.

Description

Bridge type ceramic insertion core direction adjustment device

Technical field

The present invention relates to the device in adjustment ceramic insertion core direction.

Background technology

Ceramic insertion core is the core component of the joints of optical fibre, and the feature of ceramic insertion core is that cylindrical is smooth, lightweight, quantity is large.Ceramic insertion core needs after formation through post-production, such as need one end processing wherein hydraucone, two ends chamfering etc., during due to follow-up grinding, need a large amount of ceramic insertion core to load in frock by same direction, therefore must differentiate the cephlad-caudal of ceramic insertion core before processing, direction adjusts, arrangement.Existing discriminating direction way generally adopts cylinder to promote lock pin one end close to probe, cylinder stroke is fixed, hydraucone has the degree of depth, so ceramic insertion core promotion probe moving displacement is shorter, judge that moving displacement judges lock pin direction by sensor, by rotating mechanism, lock pin is rotated again, adjustment direction is consistent.Because of hydraucone die sinking shaping after without finishing, so the degree of depth disunity, the meeting of the hydraucone depth causes erroneous judgement, and discriminating device cost is high.A kind of method is also had to rely on the feeding of shake dish to differentiate direction, utilize lock pin self gravitation, outer steps or groove to identify, select according to the way of eliminating, set feature on demand and judge, the lock pin met the demands enters next link, the ungratified Hui Zhenpan that falls continues vibrations, until meet the demands, this way cost is low, easily realize, but efficiency is low, energy consumption is high, and is subject to the impact of lock pin scale error, differentiates that error rate is higher.

Summary of the invention

Technical matters to be solved by this invention be overcome prior art above-mentioned deficiency and a kind of bridge type ceramic insertion core direction adjustment device is provided, can adjust ceramic insertion core direction quickly and accurately, installation cost is low, be easy to realize.

The present invention's adopted technical scheme that solves the problem is: bridge type ceramic insertion core direction adjustment device, the inside of cylindrical ceramic lock pin one end is hydraucone, the other end is plane, and described adjusting gear comprises base plate, feeding mechanism, driving mechanism, draw point, expeller, splicing block, tuning block; Base plate is fixed expeller, splicing block, tuning block; The end face of expeller is with pusher chute, the centre of splicing block is with vertical splicing passage, the upper port width of splicing passage is 1/2 to 2/3 of ceramic insertion core length, the end face of tuning block is with the downward-sloping tip chute of left end, the left port three of the right output port of pusher chute, the upper port of splicing passage, tip chute connects, ceramic insertion core can slide in pusher chute, tip chute, and can fall into splicing passage; Feeding mechanism conveying ceramic insertion core is in the pusher chute of expeller; The right-hand member of draw point is with the tip coordinated with ceramic insertion core hydraucone; Driving mechanism fixes draw point, moves back and forth about driving draw point, when draw point moves to right, the ceramic insertion core that draw point promotes in pusher chute slips into tip chute to the right or falls into splicing passage.

The upper cross section of preferred splicing passage is square, and width is 1/2 to 2/3 of ceramic insertion core length, and lower transition is circular, and internal diameter is greater than the external diameter of ceramic insertion core.

For monitoring this device duty, with monitoring channel in splicing block, monitoring channel and splicing channel vertical, be inserted with correlation optical fiber in monitoring channel.

Preferred driving mechanism comprises motor, offset cam, eccentric driving lever, slippage bar, guide; Motor is fixed on base plate, and the turning axle of motor fixes offset cam, offset cam is fixed eccentric driving lever, and eccentric driving lever can insert the flute profile slippage bar endoporus on slippage bar, and slippage bar is by guide part supports; Eccentric driving lever is rotated by driven by motor, and by flute profile slippage bar endoporus, rotary motion is converted to the bilateral reciprocation of slippage bar, the right-hand member of slippage bar fixes draw point.

Preferred feeding mechanism is fixed on base plate, and feeding mechanism comprises feed block, compressing rod; Feed block is fixed on the top of expeller, the feeding-passage of inclination and the binder passage of vertical direction is had in feed block, the right low left high of feeding-passage, right output port and binder passage are connected, the lower ending opening of binder passage and the pusher chute of expeller are connected, and the width of binder passage is greater than the length of ceramic insertion core; Be inserted with compressing rod in binder passage, compressing rod can move up and down; Ceramic insertion core can enter feeding-passage, slip into binder passage along feeding-passage from its left end, and by compressing rod press-in pusher chute.

Preferred above-mentioned feeding mechanism also comprises pivot arm, and the left end of pivot arm is connected with base plate by bearing pin, and the stage casing of pivot arm is with bearing, and the right-hand member of pivot arm fixes binder driving lever; The binder driving lever of pivot arm right-hand member is entangled in the compressing rod upper end of described feeding mechanism; The outward flange of the offset cam of described driving mechanism and the bearing touch of pivot arm, offset cam rotarily drives pivot arm and rotates around bearing pin.

The upper end of the right-hand member linking springs of preferred pivot arm, lower spring end is connected to the right-hand member of base plate.

Described base plate is also fixed with draw point orienting lug, and draw point extends in the pusher chute of expeller through draw point orienting lug.

Preferred pusher chute, tip chute are V-shaped groove.

Compared with prior art, the invention has the advantages that: 1, pusher chute, tip chute connects with splicing passage three, by design chute, the position of passage, width, when ceramic insertion core hydraucone is towards time right, draw point can promote ceramic insertion core and move right, hydraucone is towards falling into splicing passage, when hydraucone is towards time left, hydraucone is inserted in draw point tip, promote ceramic insertion core to the right cross splicing passage and slip into tip chute, after draw point is moved to the left, ceramic insertion core falls into splicing passage along tip chute, and hydraucone down, realize the adjustment in ceramic insertion core direction, adjustment mode is quick, installation cost is low, False Rate is low.2, increase correlation optical fiber and can monitor ceramic insertion core in splicing passage by situation, whether working properlyly monitor this device at any time.3, drive the driving mechanism of draw point simple, be easy to realize.4, in feeding mechanism, adopt the mode of feeding-passage, binder passage, compressing rod, ceramic insertion core is pressed into pusher chute, with traditional by compared with gravity blanking mode, the charging of binder mode is more stable.4, by pivot arm, offset cam etc., provide power by the compressing rod in feeding mechanism, the draw point in driving mechanism by same motor, design ingenious, simplification device structure.

Accompanying drawing explanation

Fig. 1 is the part-structure schematic diagram of the embodiment of the present invention.

Fig. 2 is the front view of the embodiment of the present invention.

Fig. 3 is the phantom view of the embodiment of the present invention.

Fig. 4 is the structural representation of ceramic insertion core.

Fig. 5 is the schematic diagram of one of the embodiment of the present invention course of work.

Fig. 6 is the schematic diagram of one of another course of work of the embodiment of the present invention.

Fig. 7 is the schematic diagram of another course of work two of the embodiment of the present invention.

Fig. 8 is the schematic diagram of another course of work three of the embodiment of the present invention.

In figure: 1, base plate, 2, motor, 3, offset cam, 4, eccentric driving lever, 5, pivot arm, 6, bearing pin, 7, bearing, 8, guide, 9, slippage bar, 10, slippage bar endoporus, 11, draw point, 12, draw point orienting lug, 13, expeller, 131, pusher chute, 14, splicing block, 141, splicing passage, 142, monitoring channel, 15, tuning block, 151, tip chute, 16, feed block, 161, feeding-passage, 162, binder passage, 17, compressing rod, 18, channel cover, 19, binder driving lever, 20, spring, 21, support, 22, ceramic insertion core, 221, hydraucone.

Embodiment

Below in conjunction with accompanying drawing, embodiment, the present invention is further described.

Embodiment, bridge type ceramic insertion core direction adjustment device as shown in Figure 1 and Figure 2, comprises base plate 1, motor 2, offset cam 3, eccentric driving lever 4, pivot arm 5, bearing pin 6, bearing 7, guide 8, slippage bar 9, draw point 11, draw point orienting lug 12, expeller 13, splicing block 14, tuning block 15, feed block 16, compressing rod 17, channel cover 18, binder driving lever 19, spring 20, support 21.

Base plate 1 is fixed on support 21.Base plate 1 is tabular, its front-back is fixed other parts of this device.

The back side fixed installation band gear buncher 2 of base plate 1, the rotating shaft of motor 2 extends to before base plate 1, offset cam 3 is fixed in motor 2 rotating shaft, offset cam 3 is positioned at before base plate 1, offset cam 3 fixedly mounts eccentric driving lever 4, when the rotating shaft of motor 2 rotates, drive offset cam 3, eccentric driving lever 4 rotate.

Above offset cam 3, arrange pivot arm 5 before base plate 1, the left end of pivot arm 5 is connected on base plate 1 by bearing pin 6 is mobilizable.The stage casing of pivot arm 5 is fixed with deep groove ball bearing 7, and deep groove ball bearing 7 can contact with offset cam 3.The right-hand member of pivot arm 5 fixes binder driving lever 19.When offset cam 3 rotates, because the coboundary of offset cam 3 can rise and fall, offset cam 3 rotation can cause deep groove ball bearing 7 dipping and heaving, because the left end of pivot arm 5 is connected by bearing pin 6, therefore, the dipping and heaving of deep groove ball bearing 7 can rotate around bearing pin 6 by driven rotary arm 5, and right-hand member, the binder driving lever 19 of pivot arm 5 also can rotate around bearing pin 6 in certain angle.Therefore, the rotating shaft translating rotation of motor 2 is that pivot arm 5 rotates in certain angle around bearing pin 6, and binder driving lever 19 moves up and down.

In order to strengthen stability when pivot arm 5 rotates, the right-hand member linking springs 20 of pivot arm 5, the other end of spring 20 is connected to base plate 1 right-hand member.

Below offset cam 3, fixed guide 8 before base plate 1, guide 8 is spill, the both sides protruding block of female guide member 8 has the chute of level, slippage bar 9 is erected on two chutes of guide 8, with slippage bar endoporus 10 on slippage bar 9, slippage bar endoporus 10 is between the both sides chute of guide 8, and the endoporus of slippage bar endoporus 10 is flute profile, flute profile endoporus can entangle eccentric driving lever 4, and the Width of flute profile endoporus and eccentric driving lever 4 interference fit, the height of vertical direction is much larger than the external diameter of eccentric driving lever 4, namely eccentric driving lever 4 can upper and lower relative movement in slippage bar endoporus 10, but can not left and right relative movement in slippage bar endoporus 10, when so eccentric driving lever 4 rotates with offset cam 3, eccentric driving lever 4 slides up and down in slippage bar endoporus 10, and stir slippage bar endoporus 10, slippage bar 9 horizontally slips, guide 8 plays the effect into slippage bar 9 slide-and-guide.The right-hand member of slippage bar fixes draw point 11, and the right end of draw point 11 is tapered tip portion, and the hydraucone of tapered tip portion and ceramic insertion core coordinates.Therefore, the turning axle of motor 2 rotarily drives offset cam 3, eccentric driving lever 4 rotates, and is converted into slippage bar 9, the moving left and right of draw point 11.

Before base plate 1, right side is fixed with expeller 13, splicing block 14, tuning block 15, feed block 16, and its position, structure are as shown in Figure 1, Figure 2, Figure 3 shows.

Expeller 13 is fixed on the below on half section, the right side of draw point 11, and the end face of expeller 13 has pusher chute 131, and the direction of pusher chute 131 is identical with the direction of draw point 11, and draw point 11 can move left and right in pusher chute 131.Preferred pusher chute 131 is V-type chute.

For preventing draw point 11 from bending distortion in movement, be fixed with draw point orienting lug 12 in the left side of expeller 13, the left and right sides of orienting lug 12 has the hole that draw point can be made to pass, and draw point 11, through this hole, plays the effect of support, guiding.

Fixation mark block 111 gone back by draw point 11, and tag block 111 is between the two side holes of orienting lug 12, and when draw point 11 moves, tag block 111 also moves thereupon, understands the moving displacement of draw point 11 by observing tag block 111.Tag block 111 also can play position-limiting action.

Splicing block 14 is fixed on the lower right of expeller 13, and with the splicing passage 141 of vertical direction in splicing block 14, by ceramic insertion core in splicing passage 141, and the upper end open width M of splicing passage 141 is 1/2 to 2/3 of ceramic insertion core length.

For preventing ceramic insertion core from blocking during landing in the splicing passage 141 of splicing block 14, the upper cross section of splicing passage 141 is square, and width M is 1/2 to 2/3 of ceramic insertion core length, and lower transition is circular, and the internal diameter at minimum place is greater than the external diameter of ceramic insertion core.

For the landing of monitoring ceramic insertion core is by the situation of splicing passage 141, quantity etc., monitoring channel 142 is also had in splicing block 14, monitoring channel 142 is vertical with splicing passage 141, correlation optical fiber is inserted with in monitoring channel 142, correlation optical fiber is connected with sensor, during when the ceramic insertion core blocking in splicing passage 141 or without ceramic insertion core landing, correlation optical fiber can sense this situation, and signal is sent to sensor, given the alarm by peripherals after sensor process, correlation optical fiber, sensor, peripherals also can be used to monitor the quantity by the ceramic insertion core of splicing passage 141 in certain period, frequency etc.

Tuning block 15 is fixed on the right of expeller 13, the upper right side of splicing block 14, and the end face of tuning block 15 has the tip chute 151 of inclination, and preferred tip chute 151 is also V-type chute.The left end of tip chute 151 is low, right-hand member is high, and the upper port of the left port of tip chute 151, the right output port of pusher chute 131, splicing passage 141 connects.

Feed block 16 is fixed on the top of expeller 13, the feeding-passage 161 of inclination and the binder passage 162 of vertical direction is had in feed block 16, the left port of feeding-passage 161 is high, connect the pipeline of conveying ceramic insertion core, the right-hand member of feeding-passage 161 is low, and right output port and binder passage 162 are connected, the lower ending opening of binder passage 162 and the pusher chute 131 of expeller 13 are connected, and the width of binder passage 162 is greater than the length of ceramic insertion core.Compressing rod 17 is also inserted with in binder passage 162, the upper end of compressing rod 17 is enclosed within outside binder driving lever 19, binder driving lever 19 is along with the rotation of pivot arm 5, compressing rod 17 is driven to move up and down, binder passage 162 extenal fixation has channel cover 18, when ceramic insertion core just in case snap in binder passage 162, detachable lower channel lid 18 is safeguarded.

The effect of feed block 16 is sent into by ceramic insertion core in the pusher chute 131 of expeller 13, its feeding process is: ceramic insertion core enters the left port of feeding-passage 161 by conveyance conduit, ceramic insertion core slides to feeding-passage 161 right output port, compressing rod 17 moves up, ceramic insertion core is entered below the compressing rod 17 in binder passage 162 by feeding-passage 161 right output port, compressing rod 17 moves down, if time in the pusher chute 131 of below without draw point 11, ceramic insertion core is pressed in the pusher chute 131 of expeller 13, if when having draw point 11 in pusher chute 131, after draw point 11 is moved to the left under slippage bar 9 drives, ceramic insertion core is pressed in pusher chute 131 by compressing rod 17.

This device adjusts the process in the direction of ceramic insertion core shown in Fig. 4 as shown in Fig. 5, Fig. 6, Fig. 7 and Fig. 8:

The profile of ceramic insertion core 22 cylindrical, wherein one end is inner with hydraucone 221, and other end is plane, and the length of ceramic insertion core 22 is L.

Ceramic insertion core 22 enters in the pusher chute 131 of expeller 13 by feed block 16, when the hydraucone 221 of ceramic insertion core 22 is at right-hand member, the plane of draw point 11 ejection ceramic insertion core 22 left end, ceramic insertion core 22 is pushed to the right output port of pusher chute 131 to the right, the upper port of splicing passage 141, due to the width M>L/2 of the upper port of splicing passage 141, and M<2L/3, so the half length working as ceramic insertion core 22 is pushed over the upper port of splicing passage 141, the right-hand member of ceramic insertion core 22 can drop into splicing passage 141 because gravity overturns downwards, now hydraucone 221 down, its process as shown in Figure 5.

When the hydraucone 221 of ceramic insertion core 22 is at left end, the taper right end of draw point 11 inserts hydraucone 221, ceramic insertion core 22 is pushed to the right output port of pusher chute 131 to the right, the upper port of splicing passage 141, because the width M of splicing passage 141 and the pass of ceramic insertion core 22 length L are L/2<M<2L/3, and the right end of draw point 11 inserts hydraucone 221, the right-hand member of ceramic insertion core 22 can not drop, and stride across the upper port of splicing passage 141, slide to the tip chute 151 of block 15, after ceramic insertion core 22 slips into tip chute 151, draw point 11 is moved to the left again, draw point 11 is separated with hydraucone 221, ceramic insertion core 22 glides along tip chute 151 under gravity, fall into splicing passage 141, now hydraucone 221 down, its process as shown in Figure 6 to 8.

The movement of draw point 11 is driven by driving mechanism, driving mechanism in this device embodiment comprises above-mentioned motor 2, offset cam 3, eccentric driving lever 4, slippage bar 9, guide 8 etc., the mechanism that certainly can produce bilateral reciprocation is a lot, driving in this device also can be replaced by other driving mechanism, as long as drive draw point to move left and right.

In this device embodiment, the feeding mechanism of ceramic insertion core comprises above-mentioned motor 2, offset cam 3, deep groove ball bearing 7, pivot arm 5, bearing pin 6, binder driving lever 19, compressing rod 17, feed block 16, channel cover 18 etc., certainly, the feeding mechanism of ceramic insertion core can be carried in the pusher chute 131 of expeller 13 a lot, and the feeding mechanism in this device also can be replaced by other feeding mechanism.

Claims (9)

1. bridge type ceramic insertion core direction adjustment device, the inside of cylindrical ceramic lock pin one end is hydraucone, and the other end is plane, it is characterized in that: described adjusting gear comprises base plate, feeding mechanism, driving mechanism, draw point, expeller, splicing block, tuning block:

Base plate is fixed expeller, splicing block, tuning block; The end face of expeller is with pusher chute, the centre of splicing block is with vertical splicing passage, the upper port width of splicing passage is 1/2 to 2/3 of ceramic insertion core length, the end face of tuning block is with the downward-sloping tip chute of left end, the left port three of the right output port of pusher chute, the upper port of splicing passage, tip chute connects, ceramic insertion core can slide in pusher chute, tip chute, and can fall into splicing passage;

Feeding mechanism conveying ceramic insertion core is in the pusher chute of expeller;

The right-hand member of draw point is with the tip coordinated with ceramic insertion core hydraucone;

Driving mechanism fixes draw point, moves back and forth about driving draw point, when draw point moves to right, the ceramic insertion core that draw point promotes in pusher chute slips into tip chute to the right or falls into splicing passage.

2. bridge type ceramic insertion core direction adjustment device according to claim 1, it is characterized in that: the upper cross section of described splicing passage is square, width is 1/2 to 2/3 of ceramic insertion core length, and lower transition is circular, and internal diameter is greater than the external diameter of ceramic insertion core.

3. bridge type ceramic insertion core direction adjustment device according to claim 1 and 2, is characterized in that: with monitoring channel in described splicing block, monitoring channel and splicing channel vertical, be inserted with correlation optical fiber in monitoring channel.

4. bridge type ceramic insertion core direction adjustment device according to claim 1, is characterized in that: described driving mechanism comprises motor, offset cam, eccentric driving lever, slippage bar, guide; Motor is fixed on base plate, and the turning axle of motor fixes offset cam, offset cam is fixed eccentric driving lever, and eccentric driving lever can insert the flute profile slippage bar endoporus on slippage bar, and slippage bar is by guide part supports; Eccentric driving lever is rotated by driven by motor, and by flute profile slippage bar endoporus, rotary motion is converted to the bilateral reciprocation of slippage bar, the right-hand member of slippage bar fixes draw point.

5. the bridge type ceramic insertion core direction adjustment device according to claim 1 or 4, it is characterized in that: described feeding mechanism is fixed on base plate, feeding mechanism comprises feed block, compressing rod; Feed block is fixed on the top of expeller, the feeding-passage of inclination and the binder passage of vertical direction is had in feed block, the right low left high of feeding-passage, right output port and binder passage are connected, the lower ending opening of binder passage and the pusher chute of expeller are connected, and the width of binder passage is greater than the length of ceramic insertion core; Be inserted with compressing rod in binder passage, compressing rod can move up and down; Ceramic insertion core can enter feeding-passage, slip into binder passage along feeding-passage from its left end, and by compressing rod press-in pusher chute.

6. bridge type ceramic insertion core direction adjustment device according to claim 5, is characterized in that:

Described feeding mechanism also comprises pivot arm, and the left end of pivot arm is connected with base plate by bearing pin, and the stage casing of pivot arm is with bearing, and the right-hand member of pivot arm fixes binder driving lever;

The binder driving lever of pivot arm right-hand member is entangled in the compressing rod upper end of described feeding mechanism;

Described driving mechanism comprises motor, offset cam, eccentric driving lever, slippage bar, guide; Motor is fixed on base plate, and the turning axle of motor fixes offset cam, offset cam is fixed eccentric driving lever, and eccentric driving lever can insert the flute profile slippage bar endoporus on slippage bar, and slippage bar is by guide part supports; Eccentric driving lever is rotated by driven by motor, and by flute profile slippage bar endoporus, rotary motion is converted to the bilateral reciprocation of slippage bar, the right-hand member of slippage bar fixes draw point;

The outward flange of the offset cam of described driving mechanism and the bearing touch of pivot arm, offset cam rotarily drives pivot arm and rotates around bearing pin.

7. bridge type ceramic insertion core direction adjustment device according to claim 6, is characterized in that: the upper end of the right-hand member linking springs of described pivot arm, lower spring end is connected to the right-hand member of base plate.

8. bridge type ceramic insertion core direction adjustment device according to claim 1, is characterized in that: described base plate is also fixed with draw point orienting lug, and draw point extends in the pusher chute of expeller through draw point orienting lug.

9. bridge type ceramic insertion core direction adjustment device according to claim 1, is characterized in that: described pusher chute, tip chute are V-shaped groove.