CN215207838U - Feeding and discharging system for spool and winding system - Google Patents

Abstract

The utility model discloses a loading and unloading system and a winding system for a spool, wherein the loading and unloading system for the spool is provided with a first movable trolley and a second movable trolley which move along the same track, the first movable trolley is provided with a reserved space for placing empty wire wheels and stacking full wire wheels, and the second movable trolley is provided with a silk thread fusing mechanism with a silk diameter measuring instrument, a full wire wheel unloading mechanism and a structure for knotting thread ends; the diameter of the silk thread at each winding machine can be measured on line, when the aerial thread wheel is installed, the manipulator at the truss robot reads the label or the bar code information on the end face of the aerial thread wheel and binds the thread diameter information with the bar code and the label, and when the subsequent full thread wheel is fed to the first mobile trolley, the label or the bar code on the full thread wheel can be effectively read again through the manipulator, so that the diameter of the silk thread wound by the full thread wheel is determined, the silk thread can be classified and stacked according to the diameter of the silk thread, manual classification is not needed, and the degree of automation is high.

Description

Feeding and discharging system for spool and winding system

Technical Field

The utility model belongs to the technical field of the spooling equipment and specifically relates to unloading system and winding system on I-shaped wheel.

Background

The winding machine is a device for winding silk threads on a spool. In order to improve the winding efficiency, a plurality of sets of winding machines are usually arranged to simultaneously perform winding so as to improve the processing efficiency.

And the yarns wound by different winding machines can be the same or different types of yarns. When the diameters of the wires wound by the plurality of winding machines are different, the full-length wire wheels obtained by winding at each winding machine need to be stacked in a partition mode according to the wire diameter of the wires wound by the full-length wire wheels.

In the conventional wire wheel feeding and discharging system, although the structure disclosed by the application number 201811256855.5 can realize automatic stacking of full wire wheels, the full wire wheels cannot be classified according to the diameters of wires wound by the full wire wheels, so that manual classification is required subsequently.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a last unloading system of I-shaped wheel and winding system in order to solve the above-mentioned problem that exists among the prior art.

The purpose of the utility model is realized through the following technical scheme:

the loading and unloading system for the spool comprises

A first moving trolley and a second moving trolley;

the first moving trolley is provided with a conveying line, an empty wheel temporary storage position, a full wheel temporary storage position and a truss robot;

the second moving trolley is provided with a 6-axis robot and a silk thread fusing mechanism, and the 6-axis robot is connected with and drives the wire wheel clamping jaw and the take-up and grabbing device to move;

the first moving trolley and the second moving trolley move along the same track,

the claw seat of the manipulator of the truss robot comprises a first bearing disc, a second bearing disc and a connecting column, wherein the first bearing disc and the second bearing disc are coaxial and are arranged up and down, the connecting column is used for connecting the first bearing disc and the second bearing disc, a through hole is formed in the center of the second bearing disc, an image acquisition device is arranged on the claw seat, and a lens of the image acquisition device faces downwards and is opposite to the through hole in the second bearing disc;

the wire fusing mechanism includes a wire diameter gauge for measuring a diameter of a wire defined thereon.

Preferably, the front end of the second bearing disc is coaxially provided with a ring-shaped magnet, and the aperture of a central hole of the ring-shaped magnet is not smaller than that of the through hole.

Preferably, the ring magnet is floatingly disposed on the second carrier plate along an axis of the second carrier plate.

Preferably, the pawl seat is provided with a proximity sensor for determining that the ring magnet is in the retracted position.

Preferably, the manipulator comprises two rotating claws and a lifting claw, the two rotating claws are arranged on two opposite sides of the claw seat, the upper ends of the two rotating claws are respectively hinged to the side part of the first bearing disc, and the middle parts of the two rotating claws are respectively pivoted with an opening and closing cylinder; the lifting claw is positioned on the side part of the second bearing plate and is connected with a lifting cylinder for driving the second bearing plate to lift.

Preferably, the lower part of the connection point between the rotating claw and the opening and closing cylinder is also pivoted with one end of a supporting piece, the other end of the supporting piece is provided with a waist-shaped hole extending along the length direction of the supporting piece, and the supporting piece is pivoted on the connecting seat on the second bearing disc through a connecting shaft penetrating through the waist-shaped hole.

Preferably, the second moving trolley is provided with a thread end fixing mechanism, the thread end fixing mechanism comprises a press roller and a telescopic cylinder for driving the press roller to move along a direction perpendicular to the moving direction of the second moving trolley, the press roller is arranged on the pivoting seat in a self-rotating manner, and the pivoting seat is in telescopic pivot connection with the cylinder.

Preferably, the thread end fixing mechanism and the thread fusing mechanism are both provided with two stages of telescopic mechanisms, and share one stage of telescopic mechanism.

The winding system comprises any spool feeding and discharging system.

The utility model discloses technical scheme's advantage mainly embodies:

according to the scheme, a first moving trolley and a second moving trolley which move along the same track are arranged, a reserved space on the first moving trolley is used for placing empty wire wheels and full wire wheels, and the wire wheels are transferred by a truss robot, a 6-axis robot and a silk thread fusing mechanism are arranged on the second moving trolley, and the 6-axis robot is connected with and drives a wire wheel clamping jaw and a take-up wire grabbing device to move; the fuse mechanism is provided with the yarn diameter measuring instrument, the diameter of the yarn at each winding machine can be measured on line, when the blank wheel is installed, the manipulator at the truss robot reads the label or the bar code information on the end face of the blank wheel and binds the yarn diameter information with the bar code and the label, and when the subsequent full-yarn wheel is fed to the first mobile trolley, the label or the bar code on the full-yarn wheel can be effectively read again through the manipulator, so that the diameter of the yarn wound by the full-yarn wheel is determined, the yarn can be classified and stacked according to the diameter of the yarn, manual classification is not needed, and the automation degree is high.

The image acquisition device on the manipulator is coaxial with the claw seat, and when the wire wheel end disc is grabbed, the image acquisition device can directly read codes, so that the operation is simpler, and the efficiency is higher.

The utility model discloses set up annular magnet on the manipulator, thereby can carry out magnetism with the I-shaped wheel effectively and inhale and create convenient condition for snatching to through making annular magnet be floating structure and setting up proximity sensor, can confirm through the position that detects annular magnet whether the centre gripping targets in place of line wheel, be favorable to guaranteeing the security of transport.

The supporting structure of the rotating claw can effectively increase the structural strength of the rotating claw, and meanwhile, the lifting claw can also effectively increase upward clamping force, so that the stability and reliability of the whole manipulator clamping ground are improved, and the carrying safety is improved.

The end of a thread fixed establishment of this scheme adopts the structure of compression roller and telescopic cylinder pin joint, and the change of silk thread position when can adapt to wire winding in advance effectively avoids the compression roller to hinder the winding of silk thread. Meanwhile, the moving structure of the thread end fixing mechanism and the silk thread fusing mechanism is simpler and more stable, and the structure is simplified.

Drawings

Fig. 1 is a top view of the loading and unloading system for the spool according to the present invention;

FIG. 2 is a perspective view of a first mobile cart and its upper structure according to the present invention;

FIG. 3 is a side view of FIG. 2;

fig. 4 is a first perspective view of the manipulator of the present invention;

fig. 5 is a second perspective view of the robot of the present invention;

fig. 6 is a bottom view of the robot in the utility model;

fig. 7 is a perspective view of a second mobile cart and its upper structure of the present invention;

FIG. 8 is a perspective view of the thread wheel clamping jaw and the thread take-up and catching mechanism of the present invention;

FIG. 9 is an enlarged view of area A of FIG. 8;

fig. 10 is a perspective view of the wire fusing mechanism and the end pressing mechanism of the present invention;

fig. 11 is an enlarged view of the region B in fig. 10.

Detailed Description

Objects, advantages and features of the present invention will be illustrated and explained by the following non-limiting description of preferred embodiments. These embodiments are merely exemplary embodiments for applying the technical solutions of the present invention, and all technical solutions formed by adopting equivalent substitutions or equivalent transformations fall within the scope of the present invention.

In the description of the embodiments, it should be noted that the terms "center", "upper", "lower", "left", "right", "front", "rear", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the devices or elements referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. In the description of the embodiment, the operator is used as a reference, and the direction close to the operator is a proximal end, and the direction away from the operator is a distal end.

The following description is made of the bobbin loading and unloading system disclosed in the present invention with reference to the accompanying drawings, as shown in fig. 1, which includes a first moving cart 100 and a second moving cart 10; the first mobile cart 100 and the second mobile cart 10 move along the same track.

As shown in fig. 1 and 2, the first moving vehicle 100 and the second moving vehicle 10 may be various AGV vehicles or RGV vehicles known in the art, and preferably, the first moving vehicle 100 and the second moving vehicle 10 are disposed on the same rail in a front-rear position relationship, and they can roll or slide along the rail.

The first moving trolley 100 and the second moving trolley 10 have the same mechanism for moving, and the first moving trolley 100 is taken as an example for description, as shown in fig. 2, a frame 110 of the first moving trolley 100 is provided with a driving motor 120, a motor shaft of the driving motor 120 is vertically downward and coaxially connected with a gear 130, the gear 130 is engaged with a rack (not shown in the figure) on the track, the driving motor 120 drives the gear 130 to rotate, and further drives the gear 130 to roll along the rack to drive the frame 110 to move along the track.

As shown in fig. 1 and 2, the first moving cart 200 is provided with a conveying line 200, an empty wheel temporary storage position 300, a full wheel temporary storage position 400 and a truss robot 500.

The conveyor line 200 is disposed on the frame 110, and is preferably a roller conveyor line, but may also be a belt conveyor line, a plate link line, or the like, and has a conveying direction perpendicular to the moving direction of the first moving cart 100. As shown in fig. 2 and 3, a row of guide wheels 210 is rotatably disposed on one side of the conveyor line above the conveying surface of the conveyor line, an axis of each guide wheel 210 is perpendicular to the conveying surface of the conveyor line, and a pallet fixing mechanism 220 is disposed on the other side of the conveyor line, the pallet fixing mechanism 220 is configured to fix a pallet 230 on the conveyor line 200 and prevent the pallet 230 from moving, and the pallet fixing mechanism 220 includes a cylinder 221 and a pressing plate 222 driven by the cylinder 221 to move towards the direction of the guide wheels 210 and higher than the conveying surface of the conveyor line 200.

Empty wheel temporary storage position 300 and full wheel temporary storage position 400 are arranged at the front side of conveying line 200, and they are arranged on the same base platform, be provided with the limiting plate on the base platform, the middle part of limiting plate is provided with the location boss, the location boss is used for fixing a position the centre bore of the line wheel axle of line wheel. Of course, the empty wheel temporary storage position 300 and the full wheel temporary storage position 400 may also be other structures capable of vertically placing the reel, and details are not described here.

As shown in fig. 2, the truss robot 500 includes a truss 510, a moving assembly 520, and a robot arm 530, which may adopt various known structures, for example, the structure disclosed in application No. 201811256855.5.

As shown in fig. 4, 5, and 6, the manipulator 530 includes a claw seat 531, the claw seat 531 includes a first tray 5311, a second tray 5312 and a connecting column 5313, the first tray 5311 and the second tray 5312 are coaxially and vertically disposed, the connecting column 5313 connects the first tray and the second tray, a through hole 5314 is formed in the center of the second tray 5312, an image capturing device 532 is disposed on the claw seat 531, a lens of the image capturing device 532 faces downward and is aligned with the through hole 5314 on the second tray, and preferably, the image capturing device 532 is coaxial with the through hole, extends into the through hole 5314, and is fixed on a mounting seat at the bottom of the second tray.

As shown in fig. 6, the manipulator 530 further includes two rotating claws 533 and a lifting claw 534, the two rotating claws 534 are disposed on opposite sides of the claw seat 531, the upper ends of the two rotating claws 534 are respectively hinged to the side portion of the first carrier tray 5311, the middle portions of the two rotating claws 534 are respectively pivoted with an opening and closing cylinder 535, and the hole 5334 on the rotating claw 533 for connecting the opening and closing cylinder 535 is a waist-shaped hole. Furthermore, the lower part of the connection point between each rotating claw 533 and the opening/closing cylinder 535 is also pivoted with the end of a supporting member 537, the other end of the supporting member 537 is formed with a waist-shaped hole 5371 extending along the length direction thereof, and the supporting member is pivoted on the connection seat 538 on the second carrier plate through a connection shaft passing through the waist-shaped hole.

As shown in fig. 6, the two rotating claws 533 include a main claw body 5331 and a claw hook 5332 detachably disposed at the end thereof, and the claw hook 5332 and the main claw body 5331 form a clamping groove 5333 approximately in a C shape, so as to grip the end plate of the pulley.

As shown in fig. 6, the lifting pawl 534 is substantially L-shaped and located at a side of the second tray 5312 and connected to a lifting cylinder 536 for driving the lifting pawl to lift, and the lifting cylinder 536 is fixed to a reinforcing plate 5315 connecting the first tray and the second tray.

As shown in fig. 6, a ring magnet 539 is coaxially disposed at a front end of the second carrier tray 5312, and a central hole of the ring magnet 539 has a diameter not smaller than that of the through hole. The ring magnet 539 is arranged on the second carrier disk in a floating manner along the axis of the second carrier disk 5312, for example, it is connected to the second carrier disk by a set of springs whose axial direction is parallel to the axis of the second carrier disk.

When the wire wheel is clamped on the manipulator, the rotating claw can drive the wire wheel to apply pressure to the annular magnet to enable the wire wheel to move to the first bearing disc direction for a certain stroke to the retraction position. A proximity sensor (not shown) is provided on the claw 531 to determine that the ring magnet is in the retracted position, and when the ring magnet moves to the sensing area of the proximity sensor in the direction of the first carrier plate, it can be determined that the reel is effectively held on the robot. When the manipulator releases the ring magnet, the spring can reset the ring magnet.

The first moving trolley and the structure on the first moving trolley are used for supplying the empty reel and stacking the full reel on the pallet. The second moving trolley and the structure on the second moving trolley are used for installing the empty wire wheel supplied by the first moving trolley on the winding machine and moving the full wire wheel to the first moving trolley.

As shown in fig. 1 and 7, the second moving trolley 10 is provided with a 6-axis robot 20 and a silk thread fusing mechanism 30, and the 6-axis robot 20 is connected with and drives the reel clamping jaw 40 and the thread taking-up and grabbing device 50 to move; the specific structure of the thread fusing mechanism 30, the reel jaw 40 and the thread take-up and take-up device 50 may be as disclosed in application No. 201921497722.7.

As shown in fig. 8, the reel clamping jaw 40 includes three L-shaped jaws 401 and a pneumatic chuck (not shown) for driving them to open and close, which form a clamping structure of a three-jaw chuck, the pneumatic chuck is fixed to an upper bearing plate 4021 of a jaw base 402, and the jaw base structure of the reel clamping jaw 40 is lengthened as required.

As shown in figure 9, a semi-circular baffle 5011 is coaxially formed at the front end of the sleeve 501 of the thread take-up and thread-grabbing device 50, a pressure head 503 is further arranged at the front end of the grabbing rod 502, and the outer diameter of the pressure head 503 is equivalent to the inner diameter of the semi-circular baffle 5011 and is larger than the diameter of the grabbing rod 502.

As shown in fig. 10 and 11, the wire fusing mechanism 30 includes, in addition to the structure disclosed in application No. 201921497722.7, a wire diameter measuring instrument 301 for measuring the diameter of a wire defined thereon, the wire diameter measuring instrument 301 being located below the fuse 302, and a detection notch thereof corresponding to a notch of a fuse head of the fuse, so that the wire diameter measurement can be simultaneously performed when the wire head is fused.

As shown in fig. 10, the second moving trolley 10 is also provided with a thread end fixing mechanism 60, and the thread end fixing mechanism 60 is used for pressing the thread end when the thread end is wound on the wire reel to start winding, so as to prevent the thread end from loosening from the wire reel under the reaction force of the winding machine. As shown in fig. 10, the thread end fixing mechanism 60 includes a pressing roller 601 and a telescopic cylinder 602 driving the pressing roller to move along a direction perpendicular to the moving direction of the second moving trolley, the pressing roller 601 is rotatably disposed on a pivoting base 603, the pivoting base 603 is telescopically pivoted with the cylinder, so as to better adapt to the change of the position of the thread during pre-winding, the telescopic cylinder 602 is connected with a linear module 604 driving the telescopic cylinder 602 to move, and the linear moving direction generated by the linear module 604 is consistent with the telescopic direction of the telescopic cylinder 602.

As shown in fig. 10, in order to simplify the structure, the wire fusing mechanism 30 also has two stages of telescoping mechanisms, and shares one stage of telescoping mechanism with the wire end fixing mechanism 60, that is, the mounting seat 303 of the wire fusing mechanism 30 is disposed on a first linear module 304, the linear moving direction of the first linear module 304 is the same as the linear moving direction of the linear module 604, the first linear module 304 is also disposed on the linear module 604, specifically, the first linear module 304 and the telescoping cylinder 602 are respectively disposed on the top surface and the bottom surface of a carrier 305, and the carrier is connected to the moving block of the linear module 604.

This scheme has further explained a winding system, includes many sets of coiling machine and paying out machine, still includes the unloading system on the I-shaped wheel, and many sets of coiling machine and paying out machine are two rows and distribute in the both sides of unloading system on the I-shaped wheel.

In addition, the winding machine is usually provided with a door capable of being automatically opened and closed, in order to avoid the situation that the door is not opened, the structure on the second moving trolley is used for loading and unloading, a door measuring sensor is further arranged on the second moving trolley, the door measuring sensor can be specifically a proximity sensor, a laser sensor and the like, when the door measuring sensor detects a signal, the door at the surface winding machine is not opened, and all mechanisms on the second moving trolley do not act and give an alarm through sound, light, electricity and the like to remind people to process.

When the whole system works, the control system controls the automatic operation of each mechanism, the specific control technology is the prior art, is not an innovation point of the scheme, and is not described herein again.

When the I-shaped wheel feeding and discharging system is used for feeding and discharging materials, the I-shaped wheel feeding and discharging system at least comprises the following steps:

and the first moving trolley and the second moving trolley both move to the side of the winding machine to be charged and discharged for blanking.

The installation seat of the silk thread fusing mechanism extends out, the 6-axis robot drives the thread picking and grabbing device to guide the silk thread between the full thread wheel and the winding machine to the position of the silk thread fusing mechanism for limiting according to the existing operation method, at the moment, the silk thread is located in the detection area of the silk diameter measuring instrument, and therefore the diameter information of the silk thread wound at the winding machine is determined through the silk diameter measuring instrument and sent to the control system.

The mechanical arm of the truss robot moves to the conveying line, a label or an identification code on the upper end face of one empty wire wheel is read, the empty wire wheel is moved to an empty wire temporary storage position, and the label or the identification code of the empty wire wheel is bound with the diameter information of the silk thread to be wound by the control system.

The 6-axis robot, the thread picking and grabbing device and the thread fusing mechanism are used for knotting the full-thread wheel on the winding machine according to the prior art, and the specific knotting process is the same as that disclosed in the application No. 201921497722.7, and details are not described here.

The 6-axis robot drives the wire wheel clamping jaw to grab the full wire wheel with the knotted wire head and place the full wire wheel on the temporary storage position.

The 6-axis robot drives the wire wheel clamping jaw to grab and install the idle wire wheel at the idle wheel temporary storage position onto the winding machine, and the 6-axis robot, the wire picking and grabbing device and the silk thread fusing mechanism wind the thread end onto the idle wire wheel for winding according to the prior art.

The mechanical arm of the truss robot moves to a full-wheel temporary storage position to read a label or an identification code on the upper end face of the full-wheel and grab the full-wheel covered wire wheel, the control system determines a stacking partition corresponding to a silk thread wound by the full-wheel according to the read label or identification code information, and the full-wheel robot moves to the stacking partition for stacking.

The utility model has a plurality of implementation modes, and all technical schemes formed by adopting equivalent transformation or equivalent transformation all fall within the protection scope of the utility model.

Claims (9)

1. The loading and unloading system for the spool comprises

A first moving trolley and a second moving trolley;

the first moving trolley is provided with a conveying line, an empty wheel temporary storage position, a full wheel temporary storage position and a truss robot;

the second moving trolley is provided with a 6-axis robot and a silk thread fusing mechanism, and the 6-axis robot is connected with and drives the wire wheel clamping jaw and the take-up and grabbing device to move;

the method is characterized in that:

the first moving trolley and the second moving trolley move along the same track;

the claw seat of the manipulator of the truss robot comprises a first bearing disc, a second bearing disc and a connecting column, wherein the first bearing disc and the second bearing disc are coaxial and are arranged up and down, the connecting column is used for connecting the first bearing disc and the second bearing disc, a through hole is formed in the center of the second bearing disc, an image acquisition device is arranged on the claw seat, and a lens of the image acquisition device faces downwards and is opposite to the through hole in the second bearing disc;

the wire fusing mechanism includes a wire diameter gauge for measuring a diameter of a wire defined thereon.

2. The bobbin loading and unloading system according to claim 1, wherein: the front end of the second bearing disc is coaxially provided with an annular magnet, and the aperture of a central hole of the annular magnet is not smaller than that of the through hole.

3. The bobbin loading and unloading system according to claim 2, wherein: the ring magnet may be floatingly disposed on the second carrier plate along an axis of the second carrier plate.

4. The bobbin loading and unloading system according to claim 3, wherein: and a proximity sensor for determining that the annular magnet is in the retracted position is arranged on the claw seat.

5. The bobbin loading and unloading system according to claim 1, wherein: the manipulator comprises two rotating claws and a lifting claw, the two rotating claws are arranged on two opposite sides of a claw seat, the upper ends of the two rotating claws are respectively hinged to the side part of the first bearing disc, and the middle parts of the two rotating claws are respectively pivoted with an opening and closing cylinder; the lifting claw is positioned on the side part of the second bearing plate and is connected with a lifting cylinder for driving the second bearing plate to lift.

6. The bobbin loading and unloading system according to claim 5, wherein: the lower part of the connecting point of the rotating claw and the opening and closing cylinder is also pivoted with the end of a supporting piece, the other end of the supporting piece is provided with a waist-shaped hole extending along the length direction of the supporting piece, and the supporting piece is pivoted on the connecting seat on the second bearing disc through a connecting shaft penetrating through the waist-shaped hole.

7. The bobbin loading and unloading system according to any one of claims 1 to 6, wherein: the second moving trolley is provided with a thread end fixing mechanism, the thread end fixing mechanism comprises a pressing roller and a telescopic cylinder which drives the pressing roller to move along the moving direction vertical to the second moving trolley, the pressing roller can be arranged on a pin joint seat in a self-rotating mode, and the pin joint seat is in telescopic pin joint with the cylinder.

8. The bobbin loading and unloading system according to claim 7, wherein: the thread end fixing mechanism and the thread fusing mechanism are both provided with two-stage telescopic mechanisms which share one-stage telescopic mechanism.

9. Winding system, its characterized in that: comprising the spool loading and unloading system as claimed in any one of claims 1-8.

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