CN205352365U - Concentricity detects feeding mechanism - Google Patents

Abstract

The utility model discloses a concentricity detects feeding mechanism, this feeding mechanism include and wherein are provided with the inclined hole by the pay -off piece that ceramic lock pin is through the inclined hole landing, the locating part, it forms spacing space, and the pay -off piece is located the one side in spacing space, the relative opposite side in spacing space is equipped with the baffle that shelters from spacing space, and ceramic lock pin comes out to fall into in the spacing space from the interior landing of inclined hole to continue the whereabouts until touchhing the baffle, have the measuring platform on inclined plane, the lower end in spacing space is located on the inclined plane, and the inclined plane is equipped with the limiting plate along length direction's both sides, and ceramic lock pin rolls until stopping on the inclined plane under the restraint of limiting plate. Utilizing the moving trajectory of ceramic lock pin self gravity and the ceramic lock pin of restraint, improving feeding efficiency, eliminate pneumatic means, let the instrument only need the power consumption to work, reduce the instrument volume greatly, possibility that reduction equipment broke down improves production efficiency.

Description

A kind of concentricity detection feed mechanism

Technical field

This utility model relates to the concentricity testing agency of detection fiber ceramic insertion core concentricity, more particularly to a kind of concentricity detection feed mechanism.

Background technology

Optical fiber ceramic lock pin, also known as ceramic ferrule, is the cylinder of precise centering in optical fiber connector plug, and there is a micropore at center, with the optical fiber that fixes.It is a kind of by nano zircite (ZrO2) material through sequence of recipe, the high accuracy special cermacis element that processes, the requirement of its endoporus aperture, endoporus out of roundness, exit orifice out of roundness and concentricity is all significantly high.So the instrument that these parameters are required for precision is tested.Because its volume is also smaller, in testing instruments, it is necessary to it automatically, is accurately transported to detection position.

Measure the instrument of concentricity at present in feeding process, the pneumatic components and parts of many employings, adopt pinpoint mode, lock pin is delivered on measurement station.Current instrument charging relies primarily on pneumatic power, it is necessary to air pump and a whole set of pneumatic components and parts, so driving instrument to need electric power and pneumatic two set dynamical systems so that instrument is sufficiently bulky, and noise is relatively big, and trouble point is many, inefficiency.

Utility model content

Feature and advantage of the present utility model are partly stated in the following description, or can from this description it is clear that or can learn by putting into practice this utility model.

For overcoming the problems of the prior art, this utility model provides a kind of concentricity detection feed mechanism, has reached to transmit the path purpose without automatic, the friction feeding of power, has improved powder feeding efficiency and improve production efficiency.

The technical scheme that the above-mentioned technical problem of this utility model solution adopts is:

According to an aspect of the present utility model, it is provided that a kind of concentricity detection feed mechanism, including:

Feed member, is provided with inclined hole, and ceramic insertion core is through described inclined hole landing；

Locating part, it forms spacing space, described feed member is located at the side in described spacing space, the relative opposite side in described spacing space is provided with the baffle plate sheltering from described spacing space, ceramic insertion core slides out in described inclined hole and falls in described spacing space, and continues to fall until encountering described baffle plate；

Having bevelled monitor station, the lower section in described spacing space is located on described inclined-plane, and both sides along its length, described inclined-plane are provided with limiting plate, and ceramic insertion core rolls until stopping under the constraint of described limiting plate on described inclined-plane.

According to an embodiment of the present utility model, described spacing space is inverted U groove.

According to an embodiment of the present utility model, between described inverted U groove and described inclined-plane, it is provided with mean for the ceramic insertion core opening rolled out outward below from described inverted U groove.

According to an embodiment of the present utility model, the width on described inclined-plane is of substantially equal with described inverted U well width.

According to an embodiment of the present utility model, the width on described inclined-plane is parallel with described inverted U groove.

According to an embodiment of the present utility model, the limiting plate of side along its length, described inclined-plane is the first limiting plate, and the limiting plate of its relative opposite side along its length is the second limiting plate, and described first limiting plate and described baffle plate are structure as a whole.

According to another aspect of the present utility model, it is provided that a kind of concentricity detection feeding method, comprise the following steps:

Ceramic insertion core enters in the inclined hole of feed member, and downward landing from this inclined hole；

Ceramic insertion core slides out in described inclined hole and falls in the spacing space that locating part is formed, and continues to fall until encountering baffle plate；

Ceramic insertion core is fallen after encountering described baffle plate on the monitor station inclined-plane below spacing space, and rolls on described inclined-plane until stopping under the constraint of the both sides limiting plate in chamfer length direction.

According to an embodiment of the present utility model, ceramic insertion core is fallen after on inclined-plane by opening the rolling out outward below from this inverted U groove between inverted U groove and described inclined-plane.

According to an embodiment of the present utility model, ceramic insertion core is parallel to described inverted U groove and falls until encountering described baffle plate in this inverted U groove.

According to an embodiment of the present utility model, ceramic insertion core is parallel to described inverted U groove and rolls on described inclined-plane until stopping.

According to another further aspect of the present utility model, it is provided that a kind of concentricity detection measuring mechanism, including:

Having bevelled monitor station, ceramic insertion core is rolled by the action of gravity of self on inclined-plane；

Rotation measuring is taken turns, described rotation measuring is taken turns several spaced apart recess on the top and its outer rim of being located at described inclined-plane and is respectively equipped with wheel spine, ceramic insertion core rolls to the wheel spine of this rotation measuring wheel lower section on described inclined-plane, and is taken turns spine will be rolled the ceramic insertion core gear got off from inclined-plane in the coarse positioning position of its side by described；

Locating slot, it is located on described inclined-plane, ceramic insertion core takes turns contact fine positioning position that rotation is driven in described locating slot and carrying out wheel measuring of outer rim and described ceramic insertion core along with being rotated further of taking turns of rotation measuring by described rotation measuring, and leaves described locating slot under the stirring of next one wheel spine.

According to an embodiment of the present utility model, inclined-plane becomes two grooves extended along its width to concave, is respectively provided with a cylindrical rod in said two groove, and described locating slot is located between two described cylindrical rods.

According to an embodiment of the present utility model, described locating slot is the V-groove being formed on described inclined-plane.

According to an embodiment of the present utility model, the side on described inclined-plane be provided with extend along its length for ceramic insertion core is carried out pinpoint limiting plate.

According to an embodiment of the present utility model, the axial direction out of plumb that the length direction on described inclined-plane is taken turns with rotation measuring, described rotation measuring wheel is made to drive ceramic insertion core rotary motion in the process in described locating slot, ceramic insertion core can move towards described limiting plate while rolling on described inclined-plane, until when this ceramic insertion core moves in locating slot, one of them end face of ceramic insertion core is fitted with the medial surface of limiting plate.

According to an embodiment of the present utility model, the outer rim of described rotation measuring wheel is provided with the soft rubber sleeve of the abrasion reduced between itself and ceramic insertion core.

According to another aspect more of the present utility model, it is provided that a kind of concentricity detection measuring method, comprise the following steps:

Ceramic insertion core is rolled on the inclined-plane of monitor station by the action of gravity of self；

The lower square wheel spine that ceramic insertion core is taken turns to the rotation measuring of the side of being provided thereon on described inclined-plane rolls, and is taken turns spine by ceramic insertion core gear in the coarse positioning position of its side by described；

Ceramic insertion core contacts, by what described rotation measuring took turns outer rim and described ceramic insertion core, the fine positioning position that rotation is driven on described inclined-plane in locating slot along with being rotated further of taking turns of rotation measuring, ceramic insertion core rotates measurement in this fine positioning position, and leaves described locating slot under the stirring of next one wheel spine.

According to an embodiment of the present utility model, ceramic insertion core accurately located position in the V-groove being formed on described inclined-plane rotates measurement.

According to an embodiment of the present utility model, ceramic insertion core is by the process in described rotation measuring wheel its rotary motion of drive to described locating slot, this ceramic insertion core moves towards the limiting plate of side, chamfer length direction while rolling on described inclined-plane, until when this ceramic insertion core moves in locating slot, one of them end face of ceramic insertion core is fitted with the medial surface of limiting plate.

According to an embodiment of the present utility model, ceramic insertion core leaves described locating slot simultaneously under described the stirring taking turns spine after having measured, next ceramic insertion core can be rolled to this coarse positioning position taking turns spine side from described inclined-plane, and then this next one ceramic insertion core is rotated measurement by the fine positioning position rotarily driven on described inclined-plane in locating slot.

Concentricity of the present utility model detection feed mechanism and method, by feed member being arranged on the side in the spacing space that locating part is formed, relative opposite side in spacing space is baffled, and it is arranged below inclined-plane in spacing space, so by gravity and motion principle, utilize ceramic insertion core self gravitation and the running orbit of constraint ceramic insertion core, reach to transmit automatic without power of path, the purpose of friction feeding, improve powder feeding efficiency, eliminate pneumatic means, instrument is allowed only to need electricity consumption to get final product work, it is greatly reduced instrument volume, reduce the possibility of device fails, improve production efficiency.

Accompanying drawing explanation

It is specifically described this utility model below with reference to accompanying drawing and in conjunction with example, advantage of the present utility model and implementation will become apparent from, wherein content shown in accompanying drawing is only for explanation of the present utility model, and do not constitute the restriction gone up in all senses of the present utility model, in the accompanying drawings:

Fig. 1 is the concentricity testing agency axonometric chart one of this utility model embodiment.

Fig. 2 is the concentricity testing agency axonometric chart two of this utility model embodiment.

Fig. 3 is the concentricity detection structure sectional view of this utility model embodiment.

Fig. 4 is the locating part structure chart of this utility model embodiment.

Fig. 5 is the structure chart that the concentricity testing agency of this utility model embodiment is viewed from above.

Fig. 6 is that the concentricity testing agency of this utility model embodiment is from the structure chart one in terms of front.

Fig. 7 is that the concentricity testing agency of this utility model embodiment is from the structure chart two in terms of front.

Detailed description of the invention

Providing a kind of concentricity testing agency in Fig. 1 to Fig. 7, for the concentricity of ceramic insertion core is detected, this concentricity testing agency includes feed mechanism and measuring mechanism.

As shown in Figures 1 to 4, this utility model provides a kind of concentricity detection feed mechanism, it for delivering to the detection position specified by ceramic insertion core 60, this concentricity detection feed mechanism includes base 10, the side of base 10 is connected by bolt is fixing with monitor station 30, and monitor station 30 is bolted to connection feed member 20 and locating part 40.

Feed member 20 is provided with inclined hole 22, inclined hole 22 is plugged with feed pipe 21, ceramic insertion core 21 enters in feed pipe 21 from inclined hole 22 Single port, this ceramic insertion core 60 is through this inclined hole 22 landing, ceramic insertion core 60 passes through the downward landing of action of gravity of self in inclined hole 22, until skidding off from inclined hole 22, the inclined hole 22 in feed member 20 limits the direction of motion of ceramic insertion core 60 and makes ceramic insertion core 60 according to fixing orbiting motion here.

Locating part 40 forms spacing space, feed member 20 is located at the side in spacing space, the relative opposite side in spacing space is provided with the baffle plate sheltering from spacing space, ceramic insertion core 60 slides out in inclined hole 22 and falls in spacing space, and continue to fall until encountering baffle plate in this spacing space, spacing space is used for retraining the direction of motion of ceramic insertion core 60 here.

Monitor station 30 is provided with inclined-plane 31, and the lower section in spacing space is located on inclined-plane 31, and both sides along its length, inclined-plane 31 are provided with limiting plate, and ceramic insertion core 60 rolls until stopping under the constraint of limiting plate on inclined-plane 31.The limiting plate of both sides, inclined-plane 31 constrains the direction of motion of ceramic insertion core 60 so that 60 meetings of ceramic insertion core are moved on inclined-plane 31, without moving to beyond inclined-plane 31.

In the present embodiment, spacing space is inverted U groove 41, and ceramic insertion core 60 can just drop in this inverted U groove 41 after sliding out in inclined hole 22, utilizes inverted U groove 41 to retrain the direction of motion of ceramic insertion core 60.Being provided with mean for the ceramic insertion core 60 opening rolled out outward below from inverted U groove 41 between inverted U groove 41 and inclined-plane 31, the size of this opening is more slightly larger than ceramic insertion core 60, makes ceramic insertion core 60 just to roll out.

In order to ensure that ceramic insertion core 60 can be rolled into inclined-plane 31 smoothly in inverted U groove 41 in the present embodiment, arrange that the width on inclined-plane 31 is of substantially equal with inverted U groove 41 width and to arrange the width on inclined-plane 31 parallel with inverted U groove 41.

In the present embodiment, the limiting plate of side along its length, inclined-plane 31 is the first limiting plate, the limiting plate of inclined-plane 31 relative opposite side along its length is the second limiting plate 80, first limiting plate and baffle plate are structure as a whole, here integrative-structure is postive stop baffle 50, this postive stop baffle 50 is simultaneously located at the side on spacing space and inclined-plane, the partial occlusion being arranged on side, spacing space on postive stop baffle 50 has lived this spacing space for blocking the ceramic insertion core fallen, postive stop baffle 50 arranges the other parts of side, inclined-plane 31 for retraining direction when ceramic insertion core 60 moves on inclined-plane 31.

As shown in Figures 1 to 4, for above-mentioned concentricity detection feed mechanism, this utility model also provides for a kind of concentricity detection feeding method, comprises the following steps:

Ceramic insertion core 60 enters in the inclined hole 22 of feed member 20, and downward landing from this inclined hole 22；

Ceramic insertion core 60 slides out in inclined hole 22 and falls in the spacing space that locating part 20 is formed, and continues to fall until encountering baffle plate；

Ceramic insertion core 60 is fallen after encountering baffle plate on monitor station 30 inclined-plane 31 below spacing space, and rolls on 31 inclined-planes until stopping under the constraint of the both sides limiting plate of inclined-plane 31 length direction.

In the present embodiment, ceramic insertion core 60 is fallen after on inclined-plane by opening the rolling out outward below from this inverted U groove 41 between inverted U groove and inclined-plane 31.

Preferably, ceramic insertion core 60 is parallel to inverted U groove 41 and falls until encountering baffle plate in this inverted U groove 41, so making ceramic insertion core 60 will not encounter the inwall of inverted U groove 41 when inverted U groove 41 falls, thus ensure that ceramic insertion core 60 direction of motion, can fall on inclined-plane smoothly.Ceramic insertion core 60 is parallel to inverted U groove 41 and rolls on inclined-plane 31 until stopping, and so makes ceramic insertion core 60 will not meet the limiting plate of its both sides when rolling on inclined-plane 31, and ceramic insertion core 60 stops after being rolled to the precalculated position on inclined-plane 31 smoothly.

As shown in Figures 5 to 7, this utility model also provides for a kind of concentricity detection measuring mechanism, for the concentricity of ceramic insertion core is accurately measured, this concentricity detection measuring mechanism includes base 10, the side of base 10 is connected by bolt is fixing with monitor station 30, and base 10 is further fixed on rotation measuring wheel 70.

Monitor station 30 is provided with inclined-plane 31, and ceramic insertion core 60 is rolled by the action of gravity of self on inclined-plane 31.

Rotation measuring is taken turns several spaced apart recess in 70 tops being located at inclined-plane 31 and its outer rim and is respectively equipped with wheel spine 71, the wheel spine 71 that ceramic insertion core 60 is taken turns below 70 to this rotation measuring on inclined-plane 31 rolls, and kept off the coarse positioning position in its side by wheel spine 71 by rolling the ceramic insertion core 60 got off from inclined-plane 31, coarse positioning position is positioned at the left side of wheel spine 71, continuing to roll after coarse positioning position ceramic insertion core 60 does brief stay, coarse positioning position is for carrying out location substantially to ceramic insertion core 60.

The quantity at least two of wheel spine 71, the quantity taking turns spine 71 in the present embodiment is three, and three wheel spine 71 are uniformly distributed.

Inclined-plane 31 is provided with locating slot, ceramic insertion core 60 takes turns 70 be rotated further and take turns contact fine positioning position that rotation is driven in locating slot and carrying out wheel measuring of 70 outer rims and ceramic insertion core 60 by rotation measuring along with rotation measuring, and leaves locating slot under the stirring of next one wheel spine 71.Ceramic insertion core 60 may proceed to scroll down through after arriving coarse positioning position, rotation measuring wheel 70 is also rotating, now the outer rim on rotation measuring wheel 70 will contact with ceramic insertion core 60, rotation measuring wheel 70 is rotated further, ceramic insertion core 60 is just rotarily driven in locating slot, in this motor process ceramic insertion core 60 can be subject to rotation measuring wheel 70 to power towards fixed-direction move.Ceramic insertion core 60 is rotarily driven to after in locating slot, 70 outer rims of taking turns rotation measuring continue to contact with ceramic insertion core 60, and along with being rotated further of rotation measuring wheel 70 drives ceramic insertion core 60 to rotate in locating slot, in the process that ceramic insertion core 60 rotates, ceramic insertion core 60 is carried out concentricity measurement by rotation measuring wheel 70.

In the present embodiment, locating slot is the V-groove being formed on inclined-plane 31, and inclined-plane 31 becomes two grooves extended along its width to concave, is respectively provided with a cylindrical rod 32 in two grooves, and locating slot is located between two cylindrical rods.Here groove is sized to just hold cylindrical rod, the smooth outer surface of cylindrical rod, it is to avoid ceramic insertion core 60 is measured and causes error, improve degree of accuracy.

The side on inclined-plane 31 be provided with extend along its length for ceramic insertion core 60 is carried out pinpoint limiting plate, limiting plate here is above-mentioned the first limiting plate being previously mentioned, and this limiting plate is used for retraining the direction of motion of ceramic insertion core 60.

Preferably, the length direction on inclined-plane 31 takes turns the axial direction out of plumb of 70 with rotation measuring, make rotation measuring wheel 70 drive ceramic insertion core 60 rotary motions in the process in locating slot, ceramic insertion core 60 can move towards the first limiting plate 50 while rolling on inclined-plane 31, until when this ceramic insertion core 60 moves in locating slot, one of them end face of ceramic insertion core 60 and the medial surface of the first limiting plate are fitted.Axial direction out of plumb due to length direction and the rotation measuring wheel 70 on inclined-plane 31, so ceramic insertion core 60 is rotated measuring and takes turns the power that can simultaneously be subject to two vertical direction in 70 processes rotarily driving locating slot, one power makes ceramic insertion core 60 move along inclined-plane 31, another power makes ceramic insertion core 60 move towards the first limiting plate, when ceramic insertion core 60 just moves in locating slot, ceramic insertion core 60 end face will be fitted with the medial surface of the first limiting plate, now ceramic insertion core 60 is just accurately positioned, and carries out concentricity measurement immediately.

In the present embodiment, the outer rim of rotation measuring wheel 70 is provided with the soft rubber sleeve 72 of the abrasion reduced between itself and ceramic insertion core 60, it is ensured that rotation measuring took turns for 70 service lifes.

As shown in Figure 1 and Figure 5, rotation measuring wheel 70 is connected with one end of a rotating shaft 73, and a straight-arm of the connector 90 of the other end of this rotating shaft 73 and a rectangular structure is flexibly connected, and another straight-arm of this connector 90 is then fixed on base 10.

Again as shown in Figures 5 to 7, for above-mentioned concentricity detection feed mechanism, this utility model reoffers a kind of concentricity detection measuring method, comprises the following steps:

Ceramic insertion core 60 is rolled on the inclined-plane 31 of monitor station 30 by the action of gravity of self；

The lower square wheel spine 71 that ceramic insertion core 60 is taken turns on 70 to the rotation measuring of the side of being provided thereon on inclined-plane 31 rolls, and by taking turns spine 71, ceramic insertion core 60 keeps off the coarse positioning position in its side.

Ceramic insertion core 60 takes turns 70 be rotated further and contact, by what rotation measuring took turns 70 outer rims and ceramic insertion core 60, the fine positioning position that rotation is driven on inclined-plane 31 in locating slot along with rotation measuring, ceramic insertion core 60 rotates measurement in this fine positioning position, and leaves locating slot under the stirring of next one wheel spine 71.

In the present embodiment, the ceramic insertion core 60 accurately located position in the V-groove being formed on inclined-plane 31 rotates measurement.

Ceramic insertion core 60 is by the process in rotation measuring wheel 70 its rotary motions of drive to locating slot, this ceramic insertion core 60 roll on inclined-plane 31 while towards side, chamfer length direction first limiting plate motion, until when this ceramic insertion core 60 moves in locating slot, one of them end face of ceramic insertion core 60 and the medial surface of the first limiting plate are fitted.

Ceramic insertion core 60 leaves locating slot simultaneously after having measured under the stirring of wheel spine 71, next ceramic insertion core can be rolled to this coarse positioning position taking turns spine 71 side from 31 inclined-planes, and then this next one ceramic insertion core 60 is rotated measurement by the fine positioning position rotarily driven on inclined-plane 31 in locating slot.

Describing preferred embodiment of the present utility model above by reference to accompanying drawing, those skilled in the art are without departing from scope and spirit of the present utility model, it is possible to have multiple flexible program to realize this utility model.For example, the feature as the shown partially of an embodiment or description can be used for another embodiment to obtain another embodiment.These are only the embodiment that this utility model is preferably feasible, not thereby limit to interest field of the present utility model that the equivalence change that all utilization this utility model description and accompanying drawing content are made is both contained within interest field of the present utility model.

Claims (6)

1. a concentricity detection feed mechanism, it is characterised in that including:

Feed member, is provided with inclined hole, and ceramic insertion core is through described inclined hole landing；

Locating part, it forms spacing space, described feed member is located at the side in described spacing space, the relative opposite side in described spacing space is provided with the baffle plate sheltering from described spacing space, ceramic insertion core slides out in described inclined hole and falls in described spacing space, and continues to fall until encountering described baffle plate；

Having bevelled monitor station, the lower section in described spacing space is located on described inclined-plane, and both sides along its length, described inclined-plane are provided with limiting plate, and ceramic insertion core rolls until stopping under the constraint of described limiting plate on described inclined-plane.

2. concentricity according to claim 1 detection feed mechanism, it is characterised in that: described spacing space is inverted U groove.

3. concentricity according to claim 2 detection feed mechanism, it is characterised in that: it is provided with mean for the ceramic insertion core opening rolled out outward below from described inverted U groove between described inverted U groove and described inclined-plane.

4. concentricity according to claim 3 detection feed mechanism, it is characterised in that: the width on described inclined-plane is of substantially equal with described inverted U well width.

5. concentricity according to claim 4 detection feed mechanism, it is characterised in that: the width on described inclined-plane is parallel with described inverted U groove.

6. concentricity according to claim 1 detection feed mechanism, it is characterized in that: the limiting plate of side along its length, described inclined-plane is the first limiting plate, the limiting plate of its relative opposite side along its length is the second limiting plate, and described first limiting plate and described baffle plate are structure as a whole.