CN205010989U - Couple formula pottery lock pin direction guiding mechanism - Google Patents

Abstract

The utility model discloses a couple formula pottery lock pin direction guiding mechanism, through the design of chute feeder, ejection of compact slide and swing arm on the pay -off piece, when ceramic lock pin from the right side to the left slipping in, if the horn mouth of ceramic lock pin a towards left side, the point portion of swing arm can catch on the horn mouth, continues to move the ceramic lock pin in back and is lifted, through on the ejection of compact slide during port, the landing of ejection of compact slide is followed to ceramic lock pin to the direction is unanimous, if chute feeder left end mouth is followed on horn mouth towards the right side, ceramic lock pin falls, the direction when falling is unanimous, has reached the purpose of adjusting ceramic lock pin direction, and according to a type collection, the realization mode is simple and convenient, quick simultaneously, and the error is few to used part is simple structure, low in manufacturing cost.

Description

Coupling type ceramic insertion core direction adjusting mechanism

Technical field

The utility model relates to coupling type ceramic insertion core direction adjusting mechanism.

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 exit skirt, other end chamfering etc., during due to follow-up ground finish, 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, exit skirt 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 exit skirt die sinking shaping after without fine limit work, so the degree of depth disunity, exit skirt depth error can cause 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 percentage error is higher.

Summary of the invention

Technical problem to be solved in the utility model be overcome prior art above-mentioned deficiency and a kind of coupling type ceramic insertion core direction adjusting mechanism is provided, rely on simple structure, the ceramic insertion core making direction unordered is quickly and accurately adjusted to and exports by same direction.

The technical scheme in the invention for solving the above technical problem is: coupling type ceramic insertion core direction adjusting mechanism, wherein one end of ceramic insertion core is with exit skirt, the other end is plane or chamfering, the length of ceramic insertion core is L, described mechanism comprises feedblock, swing arm, the upper end hinge of swing arm, with tip lower end freely and tip towards the right side; The top of feedblock has the spill chute feeder running through feedblock, ceramic insertion core can along chute feeder linear slide to the left, the inside of feedblock has discharging slideway, the upper port of discharging slideway is positioned at chute feeder bottom surface, and upper port is positioned at the left side of swing arm free state, the lower port of discharging slideway is positioned at bottom surface or the right flank of discharging opening, and ceramic insertion core can along the landing of discharging slideway straight line; The swinging track camber line of swing arm tip is crossing in same plane along place straight line with on the ceramic insertion core exit skirt in chute feeder, and wherein left side intersection point is less than L/2 to the distance of chute feeder left port; The line of centers of discharging slideway and the track tangential of swing arm tip, point of contact equals L to the length at discharging slideway upper port center, and the width of the upper port of discharging slideway is less than L/2.

Preferred swing arm upper end hinge in column, the height adjustable of column.

The chute feeder left port outer bands of further improvement has downward-sloping slideway, and ceramic insertion core can along the landing of slideway straight line.

Compared with prior art, the utility model has the advantage of: 1, by the design of feedblock, chute feeder, discharging slideway and swing arm, when in ceramic insertion core from right to left slipping, if the exit skirt of ceramic insertion core is towards a left side, exit skirt can be caught in the tip of swing arm, continues mobile rear ceramic insertion core and is lifted, through discharging slideway upper port, ceramic insertion core is along the landing of discharging slideway, and direction is consistent; If exit skirt is towards the right side, ceramic insertion core falls from chute feeder left port, and direction when falling is consistent, reach the object in adjustment ceramic insertion core direction, collect by class, implementation is easy, quick simultaneously, error is few, and used unit is simple framing member, low cost of manufacture.2, the upper end level of swing arm is adjustable, has reached the object of adjustment swing arm tip, has made this mechanism be suitable for multiple ceramic insertion core.3, chute feeder left end increases slideway, reaches the object of screening, categorised collection further.

Accompanying drawing explanation

Fig. 1 is ceramic insertion core structure cutaway view.

Fig. 2 is the main pseudosection of the utility model embodiment.

Fig. 3 is the cross section view of feedblock in Fig. 2.

Fig. 4 is the partial enlarged drawing of Fig. 2.

Fig. 5 is the ceramic insertion core moving process schematic diagram of exit skirt towards a left side.

Fig. 6 is the process schematic that ceramic insertion core falls into discharging slideway.

Fig. 7 is the ceramic insertion core moving process schematic diagram of exit skirt towards the right side.

The process schematic of Fig. 8 before to be exit skirt drop towards the ceramic insertion core on the right side.

The view of Fig. 9 after to be exit skirt drop towards the ceramic insertion core on the right side.

In figure: 1, ceramic insertion core, 11, afterbody, 12, head, 2, feedblock, 21, chute feeder, 22, discharging slideway, 3, swing arm, 31, tip, 4, another ceramic insertion core, 5, slideway.

Detailed description of the invention

Below in conjunction with accompanying drawing, embodiment, the utility model is further illustrated.

As shown in Figure 1, afterbody 11 is processed with exit skirt to the structure of ceramic insertion core 1, and head 12 does not have exit skirt, with chamfering, certainly, when head is planar end surface also can, the length of ceramic insertion core 1 is L.

Coupling type ceramic insertion core direction adjusting mechanism as shown in Figure 2 and Figure 3, adjusting mechanism comprises feedblock 2, swing arm 3 and column, the top of feedblock 2 has the chute feeder 21 of spill, chute feeder 21 runs through feedblock 2, cross-sectional width is slightly larger than the external diameter of ceramic insertion core 1, ceramic insertion core 1 horizontally slips along chute feeder 21, and during slip, ceramic insertion core can not rotate or overturn.Feedblock 2 inside has discharging slideway 22, and the upper port of discharging slideway 22 is positioned at the bottom surface of chute feeder 21, the lower port of discharging slideway 22 be positioned at the side of discharging block 2 (certainly, lower port be positioned at discharging opening bottom surface also can).Discharging slip 22 is obliquely installed, from tilting left to bottom right, and upper port is positioned at the left side of state of nature lower swing arm, the cross-sectional plane of discharging slideway 22 is circular, its internal diameter is slightly larger than the external diameter of ceramic insertion core 1, its internal diameter is the same with the spill width of chute feeder 21, and ceramic insertion core 1 along the landing of discharging slideway 22 straight line, can not rotate or overturn during landing.

After ceramic insertion core 1 puts into chute feeder 21, bell-mouthed oral area is N along the straight line at place.

The upper end hinge of swing arm 3 is in column, and lower end is swingable, and lower end is with the tip 31 of transverse direction, and during state of nature, tip 31 is positioned at chute feeder 21, and right side is pointed in tip 31.The swinging track of tip 31 is as the camber line M in Fig. 2, Fig. 4, it is crossing along place straight line N on camber line M is bell-mouthed with ceramic insertion core, camber line M and straight line N is in same plane, and during to ensure that exit skirt is moved to the left towards the ceramic insertion core on a left side, exit skirt can be inserted in tip 31.Track camber line M is crossing with straight line N in tip, and left side intersection point is an O, and some O is S to the distance of chute feeder 21 left port, and the length of S is less than 1/2 of the length L of ceramic insertion core, i.e. S<L/2.

In order to this mechanism is applicable to the ceramic insertion core of different size, column Height Adjustable, the namely height adjustable of swing arm tip 31.

Line of centers X and the track camber line M of discharging slideway 22 are tangent, and the mid point of the upper port of discharging slideway 22 is P, and some P equals the length L of ceramic insertion core to the distance f between line of centers X and the point of contact of trajectory M.The width d of the upper port of discharging slideway 22 much smaller than ceramic insertion core length L 1/2, if width d is greater than L/2, so when ceramic insertion core slips over from upper port, discharging slideway oral area can be fallen into or be stuck in ceramic insertion core no matter head or afterbody, towards a left side, all because the half length of ceramic insertion core is unsettled.

The working process of adjusting mechanism:

Feed mechanism or manually multiple ceramic insertion core is pushed chute feeder 21 from the right output port of chute feeder 21 successively, and be constantly moved to the left along chute feeder.

As shown in Figure 5, when exit skirt is moved to the left towards the ceramic insertion core 1 on a left side, due to crossing with the trajectory M of swing arm tip 31 along place straight line N on exit skirt, so when ceramic insertion core 1 is moved to the left in process, ceramic insertion core exit skirt can be inserted in tip 31, ceramic insertion core 1 continues to be moved to the left, swing arm is because swinging to upper left side by push effect power, exit skirt one end is raised in tip 31, when the head of ceramic insertion core 1 moves to the oral area of discharging slideway 22, because the line of centers X of discharging slideway 22 and trajectory M is tangent, and put P equals ceramic insertion core length L to the distance f between line of centers X and the point of contact of trajectory M, so when the head of ceramic insertion core 1 moves to the upper port of discharging slideway, the action direction of swing arm tip 31 restoring force is consistent with line of centers X, can not angle be there is because of action direction and line of centers and make ceramic insertion core 1 be stuck in the upper port of discharging slideway 22.Like this, ceramic insertion core 1 is under the effect of self gravitation, swing arm restoring force, and the head of ceramic insertion core 1 enters discharging slideway 22 down, and falls along discharging slideway 22, as shown in Figure 6.After ceramic insertion core 1 landing, swing arm tip 31 swings to the right again, and tip 31 contacts next ceramic insertion core again.

As shown in Figure 7, when exit skirt is moved to the left towards right, head towards the ceramic insertion core 4 on a left side, because head does not have exit skirt, ceramic insertion core 4 cannot be caught in swing arm tip 31.As shown in Figure 8, along with ceramic insertion core 4 continues mobile left, tip 31 landing is on ceramic insertion core 4.As shown in Figure 9, ceramic insertion core 4 continues to be moved to the left, when the part of more than the L/2 of ceramic insertion core 4 rushes examination out the left port of chute feeder 21, ceramic insertion core 4 will fall, namely when the ceramic insertion core length stayed in chute feeder 21 equals L/2, ceramic insertion core 4 starts to fall, because tip track camber line M is crossing with straight line N, left side intersection point O is S<L/2 to the distance of chute feeder 21 left port, just start to fall so the afterbody of ceramic insertion core 4 not yet moves to O point, and the left end face of the afterbody of ceramic insertion core 4 and next ceramic insertion core is close to, so the left side of next ceramic insertion core is also on the right side of an O, the tip 31 of now swing arm is on the left of an O, under the effect of restoring force, tip 31 swings to the right, tip 31 is crossed after on the right side of an O toward backswing, tip 31 just on ceramic insertion core exit skirt edge straight line below, if next ceramic insertion core be exit skirt towards a left side, so exit skirt can be inserted in tip 31, and repeat the process of Fig. 5, Fig. 6, ceramic insertion core head slips into discharging slideway 22 down, if next ceramic insertion core is head towards left, exit skirt to the right, then repeats the process of Fig. 7, Fig. 8, Fig. 9, circulate successively.

After this institutional adjustment, the ceramic insertion core marked from discharging slideway 22 lower port be all head down, exit skirt upward, and from the ceramic insertion core of chute feeder 21 left port landing be also head down, slideway 5 is set up on the left of chute feeder 21 left port, ceramic insertion core can along this slideway 5 straight line landing, equidirectional ceramic insertion core can be collected, sort out, this mechanism completes the screening of ceramic insertion core cephlad-caudal, adjustment, separation like this.

Claims (3)

1. coupling type ceramic insertion core direction adjusting mechanism, wherein one end of ceramic insertion core is with exit skirt, and the other end is plane or chamfering, the length of ceramic insertion core is L, it is characterized in that: described mechanism comprises feedblock, swing arm, the upper end hinge of swing arm, with tip lower end freely and tip towards the right side; The top of feedblock has the spill chute feeder running through feedblock, ceramic insertion core can along chute feeder linear slide to the left, the inside of feedblock has discharging slideway, the upper port of discharging slideway is positioned at chute feeder bottom surface, and upper port is positioned at the left side of swing arm free state, the lower port of discharging slideway is positioned at bottom surface or the right flank of discharging opening, and ceramic insertion core can along the landing of discharging slideway straight line; The swinging track camber line of swing arm tip is crossing in same plane along place straight line with on the ceramic insertion core exit skirt in chute feeder, and wherein left side intersection point is less than L/2 to the distance of chute feeder left port; The line of centers of discharging slideway and the track tangential of swing arm tip, point of contact equals L to the length at discharging slideway upper port center, and the width of the upper port of discharging slideway is less than L/2.

2. coupling type ceramic insertion core direction adjusting mechanism according to claim 1, is characterized in that: described swing arm upper end hinge in column, the height adjustable of column.

3. coupling type ceramic insertion core direction adjusting mechanism according to claim 1, is characterized in that: described chute feeder left port outer bands has downward-sloping slideway, and ceramic insertion core can along the landing of slideway straight line.