CN109160181B

CN109160181B - Deviation-rectifying circular belt side-supporting type optical fiber disc conveying mechanism and optical fiber disc conveying method

Info

Publication number: CN109160181B
Application number: CN201811347562.8A
Authority: CN
Inventors: 蔡永潮
Original assignee: Zhejiang Houdar Intelligent Technology Co Ltd
Current assignee: Zhejiang Houdar Intelligent Technology Co Ltd
Priority date: 2018-11-13
Filing date: 2018-11-13
Publication date: 2020-04-28
Anticipated expiration: 2038-11-13
Also published as: CN111169911A; CN111169911B; CN109160181A

Abstract

The invention relates to a deviation-correctable circular belt side-supporting type optical fiber disc conveying mechanism which comprises a rack, wherein the rack comprises two side frames which are distributed along the longitudinal direction, a belt supporting cross beam, a driving belt pulley, a conveying motor, a circular conveying belt and a driven belt pulley are arranged on the side frames, the driving belt pulley, the conveying motor, the circular conveying belt and the driven belt pulley are positioned below the belt supporting cross beam, the circular conveying belt is connected to the driven belt pulley and the driving belt pulley, the belt supporting cross beam supports the circular conveying belt, an optical fiber disc conveying groove is formed between the two side frames, and a plurality of optical fiber disc deviation-correcting mechanisms. The invention provides a deviation-rectifying circular belt side-supporting type optical fiber tray conveying mechanism capable of preventing an optical fiber tray from rolling in the conveying process without a tray, and solves the problems that the workload is increased and a space storage tray is required to be added due to the fact that the optical fiber tray is prevented from rotating by conveying the optical fiber tray loaded on the tray in the conventional optical fiber tray conveying mechanism.

Description

Deviation-rectifying circular belt side-supporting type optical fiber disc conveying mechanism and optical fiber disc conveying method

Technical Field

The invention relates to equipment for producing optical fibers, in particular to an optical fiber disk conveying method of a deviation-rectifying circular belt side-supporting type optical fiber disk conveying mechanism.

Background

In the production process of the optical fiber, the optical fiber is wound on the wire spool to form a cylindrical optical fiber disk, and the optical fiber disk needs to be conveyed through the conveying mechanism. The existing conveying mechanism is a conveying belt or a power rail which is horizontally arranged, the optical fiber disc is cylindrical, and is required to be conveyed in a tray in order to roll and move in position in the conveying process of the optical fiber disc, the tray is required to be transferred to the feeding end of the conveying belt at the discharging end of the conveying belt to recycle the tray, the increase of the tray is caused by the tray recycling work, the workload is increased during conveying, and the space is required to be increased to store the tray, so that the inconvenience is brought to field production management.

Disclosure of Invention

The invention provides a deviation-rectifying circular belt side-supporting type optical fiber tray conveying mechanism capable of preventing an optical fiber tray from rolling in the conveying process without a tray, and solves the problems that the workload is increased and a space storage tray is required to be added due to the fact that the optical fiber tray is prevented from rotating by conveying the optical fiber tray loaded on the tray in the conventional optical fiber tray conveying mechanism.

The technical problem is solved by the following technical scheme: a circular belt side-supporting type optical fiber disc conveying mechanism capable of correcting deviation comprises a frame, wherein the frame comprises two side frames which are longitudinally distributed, each side frame is provided with a belt supporting beam, a driving belt pulley, a conveying motor, a circular conveying belt and driven belt pulleys, the driving belt pulley is positioned below the belt supporting beam, the conveying motor drives the driving belt pulley to rotate, the circular conveying belt is circular in cross section, the driven belt pulleys are positioned at two ends of the belt supporting beam, the circular conveying belt is connected onto the driven belt pulleys and the driving belt pulleys, the belt supporting beam supports the circular conveying belt, an optical fiber disc conveying groove is formed between the two side frames, a plurality of optical fiber disc deviation correcting mechanisms which are transversely distributed are arranged in the optical fiber disc conveying groove, each optical fiber disc deviation correcting mechanism comprises a base, a bottom plate and two supporting rods which are longitudinally distributed are connected onto the base through a lifting mechanism, the two supporting rods are parallel, the tray rods are connected with the bottom plate through connecting rods, avoidance spaces are formed between the tray rods, the length of each tray rod is smaller than the axial size of the optical fiber disc and larger than three quarters of the axial size of the optical fiber disc, the optical fiber disc irradiating upwards is arranged on the tray rods to detect the photoelectric switch, and the optical fiber disc detecting photoelectric switches on the two tray rods are located on the vertical plane perpendicular to the tray rods.

When the optical fiber tray is used, the optical fiber tray is placed in the optical fiber tray conveying groove in a mode that the axial direction of the optical fiber tray is parallel to the extending direction of the optical fiber tray conveying groove, the optical fiber tray is supported on two radial sides through the circular conveying belts on the two side frames and is in a suspended state, the optical fiber tray is driven to move when the circular conveying belts rotate, and the optical fiber tray does not roll due to the fact that the optical fiber tray is in the suspended state that the two sides of the optical fiber tray are supported, the problem that the optical fiber tray can roll when being directly placed on the flat-plate type conveying belts is avoided. Carry through the circle conveyer belt, convenient, the conveyer belt is difficult to produce the phenomenon of sliding when the installation is fixed to be taken the area, if support through flat conveyer belt slope setting, then relatively speaking the installation fixed not very convenient and can produce the conveyer belt along the phenomenon of drive shaft axial displacement under the effect of optic fibre dish weight.

In the conveying process, the linear speed difference of the circular conveying belts at two sides can be generated due to slipping and the like, the optical fiber disc can generate axial deflection when the linear speed difference exists, and the phenomenon of deflection can also be generated when the optical fiber disc is placed on the circular conveying belts. The optical fiber disk may be deflected to touch the rack, that is, not only supported by the circular conveyor belt, but also to cause a tendency of relative movement between the optical fiber disk and the circular conveyor belt or even a phenomenon of stopping the forward movement of the optical fiber disk when the optical fiber disk touches the rack, thereby increasing the abrasion of the circular conveyor belt. According to the technical scheme, whether the optical fiber disc deflects or not can be detected in the conveying process, and the optical fiber disc can be corrected if the optical fiber disc deflects. The deviation rectifying process is that the optical fiber disc is lifted away from the far conveying belt, the optical fiber disc can be automatically aligned to be parallel to the supporting rod under the action of gravity after being lifted away from the round conveying belt, and the axis is parallel to the conveying direction when the optical fiber disc is placed on the round conveying belt again after being aligned, so that the optical fiber disc is prevented from contacting with the rack, and the abrasion phenomenon of the round conveying belt is avoided.

Preferably, the lifting mechanism is a cylinder or an oil cylinder.

Preferably, the part of the supporting rod for supporting the optical fiber disc is provided with a supporting rolling ball. The optical fiber disc can be more reliably and automatically straightened after being lifted by the supporting rod.

Preferably, the bottom plate is provided with a guide rod penetrating through the base. The phenomenon that the supporting rod is not parallel to the conveying direction due to the fact that the supporting rod moves can be prevented.

Preferably, the optical fiber disc deviation rectifying mechanism is further provided with an optical fiber disc synchronizing structure, the bottom plate comprises a lower plate and an upper plate which is arranged on the lower plate and can move along the transverse direction, the lower plate is connected with the lifting mechanism, the supporting rod is connected with the upper plate through the connecting rod, the optical fiber disc synchronizing structure comprises a rack which is arranged on the upper plate and extends along the transverse direction and a gear which is arranged on the rack and can be meshed with the upper plate when the upper plate rises, and the linear speed of the gear during rotation is equal to the linear speed of the circular conveying belt during rotation. If the spacing distance between the optical fiber trays is small, the lifted optical fiber trays may move to the lower part of the lifted optical fiber trays when the optical fiber trays are lifted and stop advancing, so that the stacking phenomenon is generated when the optical fiber trays are put down again, and the technical scheme can be used for overcoming the phenomenon.

Preferably, the optical fiber disc deviation rectifying mechanism is further provided with a barb connected to the base and located above the lower plate, and the barb is hooked on the lower plate when the gear and the rack are meshed together. The bottom plate can be prevented from being excessively lifted to damage the gears.

The invention also provides an optical fiber disc conveying method suitable for the deviation-correctable circular belt side-supporting type optical fiber disc conveying mechanism, which is characterized in that in the first step, two circular conveying belts with circular cross sections are supported at two radial sides of an optical fiber disc to suspend the optical fiber disc, and a belt supporting beam supports the circular conveying belts to prevent the circular conveying belts from sagging when the optical fiber disc is pressed on the circular conveying belts, so that the parts of the circular conveying belts supporting the optical fiber disc are kept horizontal; secondly, the driving belt pulley is driven to rotate by the conveying motor so as to drive the circular conveying belt to rotate, so that the optical fiber disc is conveyed; the optical fiber dish is sheltered from optical fiber dish detection photoelectric switch and is detected when on the mechanism is rectified to the optical fiber dish, and then the eccentricity that shows the optical fiber dish is greater than the requirement when the time difference that the optical fiber dish detection photoelectric switch on two die-pins arrived is greater than the setting value, and the optical fiber dish mechanism of rectifying is rectified the optical fiber dish that is located its top this moment, and specific process of rectifying is: the supporting rods are driven by the lifting mechanism to lift, the optical fiber trays on the circular conveying belts are lifted when the supporting rods lift, so that the optical fiber trays are separated from the circular conveying belts, the two supporting rods support the radial two sides of the optical fiber trays, the optical fiber trays are lifted by the two supporting rods and fall off the circular conveying belts, the optical fiber trays are automatically aligned to be parallel to the supporting rods under the self-weight effect of the optical fiber trays, and therefore the optical fiber trays are supported by the two circular conveying belts to convey forwards in a mode that the axes are parallel to the conveying direction of the circular conveying belts again after the supporting rods are lowered and reset. The abrasion of the circular conveying belt caused by the fact that the optical fiber disc deflects and rubs with the side frame can be avoided.

Preferably, the optical fiber discs supported by the optical fiber disc deviation rectifying mechanism and the optical fiber discs on the circular conveying belt advance at the same speed in the deviation rectifying process so as to prevent the optical fiber discs on the optical fiber disc deviation rectifying mechanism from being stacked on the optical fiber discs on the circular conveying belt when being placed on the circular conveying belt again.

Preferably, the specific process of the synchronization action is as follows: when the bottom plate is jacked up, the rack on the upper plate is meshed with the gear arranged on the rack, so that the gear drives the rack to translate to realize the transverse movement of the upper plate, and the optical fiber disc on the supporting rod is driven to move when the upper plate transversely moves.

The invention has the following advantages: the optical fiber disk can be automatically connected and placed on the optical fiber disk for conveying without rolling, so that the optical fiber disk can be conveyed without a tray; when the optical fiber disk of the optical fiber disk deflects, the optical fiber disk which generates eccentricity can be independently aligned and corrected.

Drawings

Fig. 1 is a schematic front view of the deviation-correctable circular belt side-supporting type optical fiber tray conveying mechanism.

Fig. 2 is a left side view schematic diagram of the deviation-correctable circular belt side-supporting type optical fiber disk conveying mechanism in a use state.

Fig. 3 is a schematic cross-sectional view of a base plate.

In the figure: the device comprises a rack 1, an underframe 11, a side frame 12, a belt supporting beam 121, a driving belt pulley 122, a circular conveyor belt 123, a driven belt pulley 124, a fiber tray conveying groove 13, a fiber tray deviation correcting mechanism 2, a base 21, a barb 211, a lifting mechanism 22, a bottom plate 23, a lower plate 231, an upper plate 232, a sliding groove 233, a sliding strip 234, a spring avoiding groove 235, an upper plate return spring 236, a supporting rod 24, a fiber tray synchronizing structure 25, a rack 251, a gear 252, a guide rod 26, a connecting rod 27, an avoiding space 28, a fiber tray detection photoelectric switch 29, a supporting rolling ball 20 and a fiber tray 3.

Detailed Description

The invention is further described with reference to the following figures and examples.

Referring to fig. 1 and 2, a deviation-correctable circular belt side-supporting type optical fiber disc conveying mechanism comprises a frame 1. The frame comprises a base frame 11 and 2 side frames 12 arranged on the base frame. The two side frames are longitudinally distributed. An optical fiber tray conveying groove 13 is formed between the two side frames. A belt supporting beam 121, a driving pulley 122 positioned below the belt supporting beam, a conveying motor (not shown in the figure) for driving the driving pulley to rotate, a circular conveying belt 123 with a circular cross section and two driven pulleys 124 positioned at two ends of the belt supporting beam are erected. The round conveyer belt is connected with the driven belt pulley and the driving belt pulley. The belt supporting beam supports the round conveying belt. A plurality of optical fiber disc deviation rectifying mechanisms 2 which are distributed along the transverse direction are arranged in the optical fiber disc conveying groove. The optical fiber disc deviation rectifying mechanism comprises a base 21, a lifting mechanism 22, a bottom plate 23, two support rods 24 distributed along the longitudinal direction and an optical fiber disc synchronous structure 25. The bottom plate 23 includes a lower plate 231 and an upper plate 232 movably disposed on the lower plate in a lateral direction. The lower plate is connected with the base through a lifting mechanism. The lifting mechanism is a cylinder or an oil cylinder. The lower plate is provided with at least 2 guide rods 26 which are arranged on the base in a penetrating way. The supporting rod is connected with the upper plate through a connecting rod 27. The two support rods are parallel. The supporting rod is parallel to the belt supporting beam. The carrier rods form an escape space 28 therebetween. The length of the supporting rod is less than the axial dimension of the optical fiber disc and more than three quarters of the axial dimension of the optical fiber disc, and the supporting rod can lift up only one optical fiber disc at most once. The tray rod is provided with an upward-irradiating fiber reel detection photoelectric switch 29. The optical fiber discs on the two support rods detect that the photoelectric switches are positioned on the same vertical plane perpendicular to the support rods. The part of the supporting rod for supporting the optical fiber disc is provided with a supporting rolling ball 20. The optical fiber tray synchronizing structure includes a rack 251 provided on the upper plate to extend in a transverse direction and a gear 252 provided on the housing to mesh with the rack when the upper plate is raised. When in use, the linear speed of the gear rotation is equal to the linear speed of the circular conveyer belt rotation. The optical fiber disc deviation rectifying mechanism is also provided with a barb 211 which is connected to the base and positioned above the lower plate, and the barb is hooked on the lower plate when the gear and the rack are meshed together.

Referring to fig. 3, the specific connection relationship between the lower plate 231 and the upper plate 232 is: the upper surface of the lower plate is provided with a slide groove 233. The lower surface of the upper plate is provided with a slide 234 slidably connected in the slide groove. The sliding strip is connected in the sliding groove in a sliding mode, so that the sliding connection between the upper plate and the lower plate is achieved. The slide bar is provided with a spring escape groove 235. An upper plate return spring 236 is disposed within the spring escape slot. The left end of the upper plate return spring is connected with the slide bar, and the right end of the upper plate return spring is fixed with the sliding groove. When the bottom plate is jacked up and moves to the right on the lower plate under the drive of the optical fiber plate synchronous structure 25, the upper plate return spring is compressed to store energy. When the bottom plate descends to enable the synchronous structure of the optical fiber disc to lose the driving effect on the upper plate, the upper plate moves leftwards to reset on the free-running upper plate reset spring.

Referring to fig. 1, 2 and 3, the method for conveying the optical fiber disc by the deviation-rectifying circular belt side-supporting type optical fiber disc conveying mechanism comprises the following steps: firstly, two circular conveying belts 123 with circular cross sections are supported at two radial sides of an optical fiber disc 3 to suspend the optical fiber disc, and the circular conveying belts are supported by a belt supporting beam to prevent the circular conveying belts from sagging when the optical fiber disc is pressed on the circular conveying belts, so that the parts of the circular conveying belts supporting the optical fiber disc are kept horizontal; secondly, the driving belt pulley is driven to rotate by the conveying motor so as to drive the circular conveying belt to rotate, so that the optical fiber disc is conveyed; the optical fiber dish is sheltered from optical fiber dish detection photoelectric switch and is detected when on the mechanism is rectified to the optical fiber dish, and then the eccentricity that shows the optical fiber dish is greater than the requirement when the time difference that the optical fiber dish detection photoelectric switch on two die-pins arrived is greater than the setting value, and the optical fiber dish mechanism of rectifying is rectified the optical fiber dish that is located its top this moment, and specific process of rectifying is: the lifting mechanism drives the support rods to lift, the optical fiber trays on the circular conveying belt are lifted when the support rods lift, so that the optical fiber trays are separated from the circular conveying belt, the two support rods support the two radial sides of the optical fiber trays, and after the optical fiber trays are lifted by the two support rods and separated from the circular conveying belt, the optical fiber disc is automatically aligned to be parallel to the supporting rod under the self-weight effect of the optical fiber disc, so that the optical fiber disc is supported by the two circular conveying belts to be conveyed forwards in a mode that the axis is parallel to the conveying direction of the circular conveying belts again after the supporting rod descends and resets, the optical fiber disc is prevented from being inclined and is rubbed with the side frame to cause abrasion of the circular conveying belts, and the optical fiber disc supported by the optical fiber disc deviation correcting mechanism and the optical fiber disc positioned on the circular conveying belts advance at the same speed in the deviation correcting process to prevent synchronous action of stacking the optical fiber disc positioned on the circular conveying belts when the optical fiber disc positioned on the optical fiber disc deviation correcting mechanism is placed on the circular conveying belts again. The specific process of the synchronous action is as follows: when the bottom plate is jacked up, the rack on the upper plate is meshed with the gear arranged on the rack, so that the gear drives the rack to translate to realize the transverse movement of the upper plate, and the optical fiber disc on the supporting rod is driven to move when the upper plate transversely moves.

Claims

1. A circular belt side-supporting type optical fiber disc conveying mechanism capable of correcting deviation is characterized by comprising a frame, wherein the frame comprises two side frames which are longitudinally distributed, each side frame is provided with a belt supporting cross beam, a driving belt pulley, a conveying motor, a circular conveying belt and driven belt pulleys, the driving belt pulley is positioned below the belt supporting cross beam, the conveying motor drives the driving belt pulley to rotate, the circular conveying belt is provided with a circular cross section, the driven belt pulleys are positioned at two ends of the belt supporting cross beam, the circular conveying belt is connected onto the driven belt pulleys and the driving belt pulleys, the belt supporting cross beam supports and supports the circular conveying belt, an optical fiber disc conveying groove is formed between the two side frames, a plurality of optical fiber disc deviation correcting mechanisms which are transversely distributed are arranged in the optical fiber disc conveying groove, each optical fiber disc deviation correcting mechanism comprises a base, a base plate and two supporting rods which are longitudinally distributed are connected onto the base through a lifting mechanism, the support rods are connected with the bottom plate through connecting rods, an avoiding space is formed between the support rods, the length of the supporting rod is less than the axial dimension of the optical fiber disc and more than three-quarters of the axial dimension of the optical fiber disc, the supporting rods are provided with upward-irradiating optical fiber discs detecting photoelectric switches which are positioned on the same vertical plane vertical to the supporting rods, the optical fiber disc deviation rectifying mechanism is also provided with an optical fiber disc synchronous structure, the bottom plate comprises a lower plate and an upper plate which can move along the transverse direction and is arranged on the lower plate, the lower plate is connected with a lifting mechanism, the support rod is connected with the upper plate through the connecting rod, the optical fiber disc synchronous structure comprises a rack which is arranged on the upper plate and extends along the transverse direction and a gear which is arranged on the rack and can be meshed with the upper plate when the upper plate rises, and the linear speed of the gear during rotation is equal to that of the circular conveying belt during rotation.

2. The apparatus of claim 1, wherein the lifting mechanism is a pneumatic cylinder or an oil cylinder.

3. The optical fiber disc conveying mechanism with deviation rectification function according to claim 1, wherein a supporting rolling ball is arranged on a part of the supporting rod for supporting the optical fiber disc.

4. The apparatus of claim 1, wherein the base plate has a guide rod passing through the base.

5. The apparatus of claim 1, wherein the apparatus further comprises a barb attached to the base above the lower plate, the barb being configured to engage the lower plate when the gear is engaged with the rack.