JPH0663150B2 - Rover replacement device - Google Patents

Description

Description: TECHNICAL FIELD The present invention has a bobbin wheel above a roving machine in which a tube changer, which is movable and stoppable, is arranged along a front surface of a roving machine provided with an upper support type flyer. A bobbin transfer device having a bobbin transporting tool having a large number of tube supports that can be moved along the bobbin wheel and a corresponding tube support tool corresponding to the bobbin wheel by a tube transfer machine to replace empty bobbins. is there.

BACKGROUND ART Conventionally, many proposals have been made for a tube changing device for a roving frame,
For example, as disclosed in Japanese Patent Laid-Open No. 58-98435, a conveyor belt and an automatic pipe changer are intermittently run along the front surface of the roving frame so that the conveyor belt moves substantially once. The amount of movement is doubled, empty bobbins are supplied from the end of the conveyor belt opposite to the traveling direction, and the full bobbin is carried out from the end of the traveling direction to the next process. Japanese Unexamined Patent Publication No. 50-89642 discloses that the full bobbin on the rail is taken out with its upper part and the empty bobbin on the conveyor belt is transferred to the bobbin rail with its upper part on the side opposite to the traveling direction. As described above, a pipe holding mechanism for holding a full bobbin of a roving frame and taking out two bobbins by holding it at the upper part, or supplying an empty bobbin by two bobbins at the same time by holding the bobbin at the same time is provided. Wagon format with Is composed of a Kankawa apparatus main body, and disposed a tube carrying mechanism upward along the roving frame,
A pipe holder is attached to this pipe transport mechanism, and first, a pipe support mechanism holds the upper part of an empty bobbin suspended in advance on the pipe holder and descends, and deposits the empty bobbin in a single carrier holding mechanism, Next, the pipe supporting mechanism takes out the full bobbin on the roving bobbin rail and moves up, and mounts the full bobbin taken out to the pipe holder of the pipe transport mechanism on which the empty bobbin was mounted,
Further, there is one in which the tube support mechanism is moved to supply the empty bobbin stored in the tube holding mechanism to the position where the full bobbin is taken out on the bobbin rail of the roving machine.

DISCLOSURE OF THE INVENTION Problems to be Solved by the Invention According to the above-mentioned conventional techniques, a full-threaded yarn that is once loaded with a full bobbin on a conveyor belt and then conveyed to the next step (that is, a spinning step) at the end in the traveling direction of the conveyor belt. It is necessary to transfer to the storage car with a full yarn unloader. When these storage cars and unloaders are of a wagon type so that they can be moved between multiple rovings, when the trolleys that move between rovings are loaded with these storage cars, unloaders and pipe changers. The control becomes complicated so that interference does not occur in the movement. Further, since it is necessary to lift the full bobbin from the storage car to the spinning creel again, a device for lifting the full bobbin is also required for automation, and there is a problem that the equipment becomes large. Moreover, since the conveyor belt is provided along the front surface of each roving frame, there is a problem that the path between the roving frames becomes narrow. Moreover, according to the above, since the pipe support mechanism is provided so as to hold the upper part of the bobbin when the empty bobbin is transferred to the pipe transport mechanism above the roving frame, this pipe support mechanism is used. It is necessary to move to a position very close to the pipe holder of the transfer mechanism, and the height of the pipe changer itself is such that the bobbin suspended by the pipe transfer mechanism and the upper part of the pipe changer overlap in the vertical direction. It was Therefore, it is difficult to take a layout in which the layout of the pipe transport mechanism and the moving rails of the pipe changer in the factory overlaps or intersects in a plane, and there is a limit to the layout in the factory and the height of the pipe changer itself. Is relatively high, there is a risk that the bobbin delivery operation with the tube holder may become unstable.

Means for Solving the Problems In order to solve the above-mentioned problems of the prior art, the present invention provides a bobbin conveyor having a plurality of tube supports along a bobbin wheel row of a roving machine. In the tube changing device of the roving machine, which is arranged so as to be movable along the front surface of the spinning machine, the empty bobbin previously hung on the tube support and the full bobbin on the bobbin wheel are sequentially replaced by the tube changing machine. , The pipe changer is equipped with bobbin wheels and corresponding pegs for the bobbin wheel at the time of pipe replacement, and peg bars for empty bobbins, respectively, and these peg bars are at least full with the bobbin wheel to transfer the empty bobbin The common lower transfer position and the pipe support are full, and the upper and lower transfer positions for transferring the empty bobbin are equipped so that they can be moved up and down by lifting devices so that they do not interfere with each other during the lifting operation. This tube The replacement machine has the full bobbin upper part on the bobbin wheel, takes out the full bobbin onto the full bobbin peg bar at the common lower delivery position, and has the upper part of the empty bobbin on the empty bobbin peg bar at the common lower delivery position. It is characterized by comprising a delivery device configured to feed the empty bobbin onto the bobbin wheel.

According to the above-mentioned means, at the time of pipe replacement, at the lower delivery position, the upper part of the full bobbin is held by the delivery device and the full bobbin is placed on the full bobbin peg bar and lifted to insert the full bobbin into the pipe support. The empty bobbin previously hung on the corresponding pipe support is placed on the empty bobbin peg bar at the upper delivery position and the empty bobbin peg bar is lowered to move the full bobbin by the delivery device at the lower delivery position. Supply an empty bobbin onto the bobbin wheel after taking it out.

Embodiments In FIGS. 1 to 3, reference numeral 1 denotes a roving machine, and upper supporting flyers 3 ... Suspended in a front and rear rows on its top rail 2 in a staggered manner, and the upper supporting flyers 3 ... Each group of four keeps its adjacent pitch at P1, and the pitch between adjacent flyers in this group is kept at P2, and the front-rear spacing is set to L. The flyers 3 ... are inside the top rail 2. It is rotated at high speed via the drive shaft and gears that are provided. A bobbin rail 4 is arranged below the flyers 3 so as to be able to move up and down, and bobbin wheels 5a and 5b concentric with the flyer 3 are arranged on the bobbin rail 4 to rotate at high speed via a drive shaft and gears. To be done.

Next, the pipe replacement device will be described. The tube changer is a roving machine 1.
And a transfer device CR for the roving bobbin above the roving spinning machine 1. First, the pipe changer
Explain AD. In the pipe changer AD, the pipe changer body 6
A pair of traveling wheels 9, 9 integral with an axle 8 are rotatably supported on a bottom plate 7 of the axle 8 through a bearing 10 in the front-rear direction of the traveling direction, and are driven by one axle 8 (left side in FIG. 3). The pulley 11 is integrally mounted, and the timing belt 14 is suspended between the driving pulley 13 of the traveling motor 12 on the bottom plate 7. The respective traveling wheels 9, 9 are laid on the front floor surface of the roving frame 1 over the entire length in the longitudinal direction of the roving frame 1 for the traveling line 1.
It is mounted so that it rolls on 5, 15. Further, on the floor surface, a proximity body 16 is arranged along the longitudinal direction of the machine base for each staff center of the bobbin wheels 5a, 5b (hereinafter referred to as the replacement centers CL1, CL2 ... of the roving machine 1). There is. On the other hand, on the bottom plate 7 of the main body 6 of the pipe changer, at the center of the pitch of the second and third front and rear pipe changer arms of the pipe changer bars described later (hereinafter, the pipe change center CL When a proximity switch 17 capable of detecting the proximity body 16 is attached and the traveling motor 12 is driven, the pipe changer AD moves along the traveling rails 15 and 15 along the front surface of the roving frame. When the proximity body 16 and the proximity switch 17 face each other, the proximity body 16 and the proximity switch 17 are stopped at a predetermined pipe replacement position.

Next, the full bobbin and empty bobbin peg bars 18, 19 of the pipe changer body 6 and the respective lifting devices will be described. The full bobbin peg bar 18 is provided in a row on the upper surface thereof, and the pegs 20 with adjacent peg intervals set to the bobbin pitch P of the spinning creels are provided for one staff member (four), and each peg bar 18 is provided.
20 is slidable in the vertical direction with respect to the upper surface of the full bobbin peg bar 18, is upwardly urged by a spring 21, and its upper end is positioned by a retaining screw 22. This has the same structure as the peg 20 of the empty bobbin peg bar 19 described later (see FIG. 6). The full bobbin peg bar 18 has guide blocks 23, 23 fixed to the left and right ends thereof, and the guide blocks 23, 23 extend from the bottom plate 7 of the pipe changer body 6 to the top plate 24.
Up and down slide block 26, which is vertically slidably mounted on two parallel guide bars 25, 25, which are slidably mounted vertically on a second guide bar 27. Has been done. The front ends of the left and right guide blocks 23, 23 and the front faces of the left and right slide blocks 26, 26 are rotatably pin-connected to one ends of the first and second link members 28, 29, respectively. A pin 31 on the slide block 26 side is located vertically below 30. The other ends of the first and second link members 28 and 29 are rotatably pin-connected by a support shaft of a cam follower 32. On the other hand, on the side plates 33, 33 on the left and right outer sides of the front guide bars 25, 25 of the pipe changer body 6, the cam followers 32, 32 are opposed to the side plates 33, 33 so that they are pushed upward as shown in FIG. Cam plates 34, 34 having slopes 34a are mounted over substantially the entire length of the pipe changer body in the vertical direction.
A drive shaft 35 is rotatably supported on the bottom plate 7 between the side plates 33, 33 along the traveling direction of the pipe changer AD.
Drive sprockets 36, 36 are fixed between the guide bars 25, 25 and the side plates 33, 33 of 35, and one end of the drive shaft 35 further protrudes from the side plate 33 toward the traveling wheels to form a sprocket.
37 is fixed. A chain 40 is suspended between the sprocket 37 and the sprocket 39 of the rotary shaft of the drive motor 38. Above the drive sprockets 36, 36, driven sprockets 41, 41 are rotatably supported at positions close to the top plate 24 corresponding to the drive sprockets 36, 36, respectively. Elevating chains 42, 42 are respectively suspended between 41, and intermediate portions of the respective elevating chains 42 are slidable as shown in FIG.
Is fixed to the side surface of the traveling wheel. In this way, the rotating device for the full bobbin peg bar 18 is constructed, and as shown in FIG. 5, the slide blocks 26, 26 move up and down by the raising and lowering of the raising and lowering chains 42, 42, and the slide blocks 26, 26.
As a result, the full bobbin peg bar 18 rises while the distance between the left and right cam followers 32 is contracted by engagement with the cam 34 and pushed up against the slide blocks 26, 26.
The upper delivery position (upward end) S4 where the full bobbin FB is inserted into the bobbin transport tool 114 described below, and the full bobbin FB extracted from the bobbin wheels 5a and 5b by the pipe replacement bar described below is placed on the full bobbin peg bar 18. Receiving position S2 of the lower delivery position to be mounted on the peg 020 and the preparation position of the lower delivery position below this.
It is designed to move vertically between S1 (downward end).

Next, as shown in FIGS. 1 to 3 and 6 to 8, the empty bobbin peg bar 19 has the pegs 20 of the full bobbin peg bar 18 on the upper surface thereof in the same manner as the full bobbin peg bar 18.
In the front-rear direction, a row of pegs 20 adjacent to each other in a row and having a pitch P of the spinning creel is provided for one staff member (4 pieces), and each peg 20 is a peg bar for an empty bobbin as described above. 19 It moves up and down with respect to the upper surface, and is biased by preventing it from coming out upward. The lifting device for the peg bar 19 for empty bobbins is as follows. A second guide bar 43, which is slightly obliquely rearward of each of the guide bars 25, 25,
43 is installed in parallel with the guide bars 25, 25, and each guide bar 43,
Elevating blocks 44, 44 are fitted on the 43 so as to be able to move up and down. A cam lever 46 having a cam follower 45 at the tip on the side plate 33 side is key-connected to each of the elevating blocks 44 at one end of a shaft 47 that rotates with respect to the elevating block 44, and swings in the front-rear direction to swing the shaft 47. A sector-shaped sector gear 48 is key-connected to the other end. The sector gear 48 meshes with a gear 51 of a swing arm 50 that is swingably supported in a vertical direction on a support shaft 49 that is fixed to the lift block 44 so as not to rotate. The swing arm 50 sandwiches a fixed shaft 52 at its tip, and the fixed shaft 52 is rotatable with respect to the timing belt pulley 53 integrally fixed to the empty bobbin peg bar 19 on both left and right sides thereof. Is loosely fitted to. Further, a timing pulley 54 is attached to the tip of the support shaft 49.
Is key-connected so as not to rotate relative to the elevating block 44, and a timing belt 56 is suspended between the timing pulley 54 and the timing pulley 53 via a tension pulley 55 so as to oscillate. Even if the moving arm 50 swings, the empty bobbin peg bar 19 keeps the horizontal state. On the bottom plate 7 of the main body 6 of the pipe changer, drive sprockets 57, 57 are fixed to a drive shaft 58 at the rear positions of the guide bars 43, 43 and are rotatably supported. The sprocket 59 is fixed, and the drive chain 62 is suspended between the sprocket 61 of the drive motor 60. Above the drive sprockets 57, 57 are driven sprockets 63, 63 corresponding to the drive sprockets 57, 57 in the vertical direction.
Is vertically supported near the top plate 24, and an elevating chain 64 is suspended between the drive and driven sprockets 57 and 63, and an intermediate portion thereof is connected to the rear surface of the elevating block 44. Further, inside the left and right side plates 33, 33, the cam followers are respectively
Groove cam plate 65 having a cam groove 65a into which 45 is fitted and guided
Is stuck. In the cam groove 65a, the empty bobbin peg bar 19 is moved along the locus T as shown in FIG.
The center of the peg is located behind the guide bar 43 so that the full bobbin peg bar 18 does not interfere with the vertical movement of the full bobbin FB on which the full bobbin FB is placed, so that the empty bobbin EB is received from the bobbin carrier 114. (Upward end) S8 and below the machine base, the lower end height of the empty bobbin EB on the empty bobbin peg bar 19 is higher than the upper end heights of the bobbin wheels 5a and 5b of the bobbin rail 4 (state shown in FIG. 1) lowered to the pipe replacement state. It is located at a slightly higher position, and is moved up and down between the receiving position S6 of the lower delivery position where the empty bobbin EB is passed to the front and rear tube replacement arms, which will be described later, and the completion position S5 of the lower delivery position below this. And, moreover, the cam groove so that the upper delivery position S8 of the empty bobbin peg bar 19 and the receiving position S6 of the lower delivery position and the completion position S5 are the same as the respective positions S4, S2, S1 of the full bobbin peg bar 19. The shape is set and the back-and-forth movement mechanism is also Together with this, an elevating device for the peg bar 19 for empty bobbins is constructed.

Next, a delivery device for a full and empty bobbin will be described with reference to FIGS. 1 to 3 and 9 to 11. Brackets 67, 67 are arranged on the bottom plate 7 of the pipe changer body 6 at equal positions to the left and right with respect to the pipe change center CL, and horizontal guide bars 68, 68 are provided between the brackets 67, 67 and the rear plate 66. Further, a supporting block 70 is fixed horizontally on the tube replacement center axis, and between the rear plate 66 and the horizontal bar 68, a feed bar 69 parallel to the horizontal bar 68 is rotatably supported. There is. A sprocket 71 is attached to the end of the rear plate 66 of the feed bar 69.
Is fixed, and a chain 86 is suspended between the sprocket 71 and the sprocket 85 of the motor 84. This feed bar
The feed screw 72 is engraved on the 69 over substantially the entire length.
A leg of a gate-shaped slide base 73 is fitted to the horizontal guide bars 68, 68 so as to be movable back and forth, and a plate 74 is attached to the lower surface of the leg.
Is fixed, and on the plate 74, a feed bracket 75 having a female screw in which the feed screw 72 of the feed bar 69 is screwed.
Is stuck. Elevating bars 77, 77 hung vertically from the left and right lower portions of the pipe replacement bar 76 are fitted on the upper part of the legs of the slide base 73 so as to be vertically movable.
A lifting screw rod 78 is hung vertically between the right and left sides of the 77, 77, and the screw rod 78 is screwed to a feed screw portion 80 at the center of a drive sprocket 79 supported by a slide base 73 so as to be horizontally rotatable. A chain 83 is suspended between a drive sprocket 79 and a sprocket 82 of a drive motor 81 fixed to a slide base 73. Therefore, the pipe replacement bar 76 can be moved back and forth and moved up and down toward the front side of the roving frame. This replacement bar 76
Is open at the top surface as shown in FIG. 10, and sliding surfaces 84, 84
The front and rear row slides 85, 86 formed on the sliding surface 84, 84 are formed on the sliding surfaces 84, 84 as shown in FIG. From the left side as viewed from the rear of 6, the front row, the rear row, and so on are alternately placed, and can be moved only in the left-right direction by slider holders 87, 88 on the front and rear of the pipe replacement bar 76. Two spline shafts 89, 90 are rotatably supported on the pipe replacement bar 76 along the machine longitudinal direction.
The two spline shafts 89, 90 are connected at one end thereof to a drive motor 92 via a gear train 91. Groove cams 93 with cylindrical cam grooves 93A, 93B engraved on both sides are slidably fitted to the spline shaft 89 in correspondence with the front and rear row sliders 85, 86. The left and right movement restricting members 94 of the groove cam 93, which are in sliding contact with the left and right ends of the cam 93, are the pipe replacement bars 76.
It is stuck to. On the lower surface of the front and rear row sliders 85 and 86, cam followers 95 are located at positions corresponding to the cam grooves 93A and 93B.
And these cam followers 95 engage with the corresponding cam grooves, respectively, and the front and rear row sliders 85, 86 straddle two adjacent groove cams except those at both ends thereof. When the cams 93A and 93B rotate by a predetermined angle θ (between points A and B) shown in FIG. 10, the pitch between sliders becomes P1.
From formed to change from P to P (or vice versa),
A device for changing the left-right distance between the rear row tube replacement arms is configured. The front row slider 85 integrally includes a front row tube replacement arm 96 that can face the bobbin wheel 5a row of the roving frame 1, and is formed with a fork having two ends so that the collar portion B1 at the upper portion of the bobbin is supported from below. I am doing it. Further, the rear row slider 86 is provided with a rear row pipe replacement arm 97 that can face the bobbin wheel 5b row. This rear row pipe replacement arm 97 is a two-pronged fork at the tips of the left and right guide rods 98, 99. Equipped with the sliding hole 99 of the rear row slider 86,
The guide rods 98, 98 are inserted through 99 so as to be slidable in the front-rear direction. A rack 100 is engraved on the lower side of the guides 98, 98, and a pinion 101 rotatably supported by a rear row slider 86 is meshed with the rack 100, and the spline shaft is provided at the center of the pinion 101. 90 is spline-fitted, and the spline shaft 90 is loosely fitted to the front row slider 85 to form a front / rear distance changing device for the front and rear row pipe replacement arms 96 and 97. Further, the number of teeth of each gear of the gear train 91 is just the rear-row replacement arm when the spline shaft 89 rotates by θ.
97 is set to move by L, and as shown in FIG. 11, a change operation from the staggered arrangement of one staff of the roving machine 1 to a state in which it corresponds to the bobbin arrangement of the spinning creels in one line (or vice versa). Is synchronized with one drive motor 92. Proximity switches SW1 to SW8 are arranged at predetermined positions in the vertical direction inside the left and right side plates 33 of the pipe changer body 6, and the proximity switches SW1 to SW4 are the full bobbin peg bars 18
For detecting the proximity body 102 mounted on the slide block 26, in order from the proximity switch SW1, the preparation position S1 of the lower delivery position of the full bobbin peg bar 18, the receiving position S2 of the lower delivery position slightly elevated from it, Checking each of the intermediate stop position S3 and the upper delivery position S4, the drive motor 38 is stopped to stop the full bobbin peg bar 18 at each position, and the proximity switches SW5 to SW8 are set to the empty bobbin peg bar 19 respectively. Proximity body protruding from the rear surface of the slide block 44 of
103 is detected, and in the order from the proximity switch SW5, the completion position S5 of the lower delivery position of the empty bobbin peg bar 19, the receiving position S6 of the lower delivery position slightly elevated from it, the standby position S7 shown in FIG. 8, and Check each of the upper delivery positions S8,
The drive motor 60 is stopped to stop the empty bobbin peg bar 19 at each position. Further, LS1 to LS3 shown in FIG. 3 are the retracted ends of the slide base 73 and the delivery positions (the front and rear row pipe replacement arms 96 and 97 forks in a single row vertically above each peg 20 of the full bobbin peg bar 18). Corresponding to each other), and the zigzag bobbin wheels 5a and 5b on the zigzag front and rear row tube replacement arms 96 and 97 with the limit switch for confirming the corresponding forward ends of the slide switches.
The slide base 73 is stopped at each position by being actuated by the dog 104 attached to the leg of 73. Furthermore, a dog is attached to one slide bar 77 on the lower surface of the pipe replacement bar 76.
105 is mounted, and limit switches LS4, 5 are arranged above and below the slide base 73 via brackets. The limit switches LS4, 5 confirm the rising end and the falling end of the pipe replacement bar 76, and the pipe replacement bar 76 To stop at the husband's position.

Next, the roving bobbin transporting device CR will be described with reference to FIGS. 2 and 12 to 17. A main carrier rail 110 connecting the roving machine 1 and a creel of a spinning machine (not shown) is installed above the machine base end side, and a branch carrier rail 111 on the roving machine side is connected to the main carrier rail 110 via a switching device 112. There is. This branch transport rail 111 is used for bobbin wheels 5a and 5b of the roving machine 1.
Along with the peg bar for full bobbin of the pipe changer AD when changing pipes
It is hung vertically above 18 and circumvents the out-end side of the machine base, and is arranged behind the machine base. These transport rails 11
As shown in FIG. 15, 0 and 111 have a cross-sectional shape formed into a rectangular cross section having an opening at the bottom, and wheels 113 roll inside the transport rails 110 and 111 to transport a roving bobbin. Tool 1
14 is designed to run along the transport rails 110 and 111. A plurality of (six in this embodiment) tube supports 116 are suspended below the substrate 115 of the bobbin carrier 114 while maintaining the bobbin pitch P of the spinning creels in the longitudinal direction. Further, the long conveyor bobbin 118 is formed by connecting through a connecting rod 117 and connecting enough to hang a roving bobbin for one roving machine. The pipe replacement center of the transport tool station 118 is L1 every 4 · P from the center between the second and third lines.
It is as L2. Next, 119 is a transfer device for transferring the transfer tool station 118 to the transfer rails 110 and 111.
A plurality of sets are arranged at intervals shorter than the entire length of. The transfer device 119 includes a swing arm with a vertical shaft 121 as a center on both sides of a base 120 fixed on the transfer rails 110 and 111.
The swing arm 122 supports the 122 swingably in the horizontal direction.
One side rotatably supports a rotating disk 123, and the other side has a rotating disk 125 connected to a drive motor 124.
The substrate 115 of the bobbin transport tool 114 is sandwiched from both sides by the force of the spring 126 so as to face the 123, and the rotary disk 125 is positively driven to transport the transport tool string. Next, several bobbin transport tools 11 at the rear of the bobbin transport tool train (on the right side in FIG. 19).
On the board 115 of 4, indexing positioning pins protruding to both sides
127 indicates the mutual pitches of the number of times of pipe replacement stops of one roving spinning machine, and the mutual pitches thereof are set to one moving pitch (3 · P1 +
P2) and the tube replacement center pitch (4 · P) of the bobbin transfer tool 114 are fixed and maintained at a difference P4 (= 4 · P-3 · P1-P2). Then, a proximity switch PX that detects the indexing positioning pin 127 is attached via a bracket 128 from the transport rail 111, and a catcher 129 swings by the operation of the cylinder 130 on the opposite side of the proximity switch PX, and transports. Guren 11
When 8 is in the first pipe replacement position L1, the first indexing positioning pin 127 faces the proximity switch PX and is engaged with and disengaged from the indexing positioning pin 127. Feeds one pitch (P4) at the time of pipe replacement by the control circuit 210 shown in FIG. 17, sends a roving bobbin (full) to the spinning machine side after pipe replacement, or sends an empty bobbin EB before pipe replacement. When the suspended carrier device 118 is transported to the front surface of the predetermined roving frame 1, continuous feeding is performed. Of this circuit, the controller SPC controls the drive motor 124, and contacts the motor ON / OFF, rotation speed, and rotation direction with the contact RMH-.
It is controlled by opening and closing the first and the like. The switching device 112 is attached to the upper end of the support shaft 131 and a carrying path switching plate 132 mounted on the transport rail 110 so as to swing horizontally around the support shaft 131 integrally with the support shaft 131. And an oscillating arm 134 that oscillates by the forward and backward movement of the.

The following operation will be described. First, in response to a full pipe advance notice command of the roving frame 1, the transport tool chain 118 in which the empty bobbin EB is suspended in advance is transferred from the main transport rail 110 to the branch transport rail 111 in front of the roving frame 1. At this time, the transfer device 119 closes the contact Hi of the high-speed switch of the circuit 205 and the contact R of the reverse switch of the circuit 207 shown in FIG. 17, so that the relays RTH and RTHR are excited and the circuit 208
The normally closed contact RTH-1 opens and the catcher cylinder 130
Solenoid SO of solenoid valve not shown connected to
L is switched, the cylinder 130 moves forward, and the catcher 129 moves upward. At the same time, the contact RTHR-1 connected to the controller SPC of the circuit 209 is closed and at the forward end of the cylinder 130, the forward end limit switch LSA (circuit 200) is turned on, and the relay RLSA is turned on. Then contact point RLSA of circuit 2065
-2 is closed and the relay RMH is turned on, and the contact RMH of the circuit 209-
1. The RMH-2 is closed, the drive motor 124 of the transfer device 119 is reversed at high speed to transfer the transport tool train 118 at high speed by the rotating disk 125, and the tip of the transport tool train 118 is shown in FIG. 19 (A). As the proximity switch 135 confirms, the contact Hi of the circuit 205 is opened, the solenoid SOL is switched, and the cylinder 130 is retracted to the first position.
The indexer positioning pin 127 is engaged with the catcher 129, and the pipe replacement center L1 of the transport tool chain 118 is aligned with the pipe replacement center CL1 of the roving machine 1 and stopped at the first pipe replacement position. Then, in response to a full pipe command of the roving frame 1, the pipe changing machine AD is placed on the front surface of the roving frame 1, and the first proximity body 16 and the proximity switch 17 face each other and are stopped at the first pipe changing position. The pipe replacement centers CL, L1, and CL1 of the replacement machine AD, the conveyor device station 118, and the roving machine 1 are the same (second and third).
Figure). At this time, the pipe replacement bar 76 is at the descending end and the retracting end, and the full bobbin peg bar 18 is at the lower delivery position preparation position.
In S1, the empty bobbin peg bar 19 is in the standby position S7 (No.
18 (A)). Next, while the pipe replacement bar 76 is at the descending end and the retreat end, the pipe replacement arms 96, 97 for the front and rear rows are changed from the one-row arrangement to the Sentori arrangement, and the feed bar 69 is rotated to move the pipe replacement bar 76. The bobbin rail 4 is moved forward toward the full bobbin FB and stopped at the forward end, and the front and rear row tube replacement arms 96,
Insert the fork part of 97 under the upper collar part BT of the full bobbin FB and rotate the lifting screw rod 78 to raise the pipe replacement bar 76 to the ascending end, and attach it to the front and rear row pipe replacement arms 96 and 97. Suspend the full bobbin FB. At this time, the empty bobbin peg bar 19 is at its standby position.
The four empty bobbins EB of the transport device string 118 at the pipe changing position are placed on the peg 20 while being moved upward from S7 by driving the lifting chain 64 and moved up to the upper delivery position S8. (Fig. 18 (B)). Then the peg bar for empty bobbins
19 is the standby position with the empty bobbin EB being lowered and retracted
Stop at S7, and at the same time the pipe replacement bar 76 is retracted, the pipe replacement arms 96, 97 for the front and rear rows are arranged in a line from the staggering with the full bobbin FB hanging, and each peg of the full bobbin peg bar 18 is just right. The full bobbin FB taken out vertically above 20 is stopped at the delivery position where the full bobbin FB is slightly raised, and the full bobbin FB is placed on each peg 20 at the receiving position S2. (Fig. 18 (C)). Next, the pipe replacement bar 76 is retracted to the retracted end, the elevating chain 42 is driven to raise the full bobbin peg bar 18 vertically upward, and the full bobbin FB is attached to the empty pipe support 116. At the same time, the empty bobbin peg bar 19 in the standby position S7, the upper collar portion BT of the empty bobbin EB, the front, rear row pipe replacement arm 96 of the pipe replacement bar 76 at the rising end and the retreat end in a single row state, The robot is lowered and moved forward to the receiving position S6 so that the height of 97 can be inserted (Fig. 18 (D)). Next, the full bobbin peg bar 18 is lowered and stopped at the intermediate stop position S3, and the front and rear row pipe replacement arms 96 and 97, which are in the ascending end and the retreat end in a single row, are moved forward and stopped at the delivery position. Then, the empty bobbin EB is inserted below the upper collar portion BT, and then the empty bobbin peg bar 19 is slightly lowered to the completion position S5 of the lower delivery position, and the front and rear row pipe replacement arms 96 and 97 are empty. Suspend the bobbins EB in a line (Fig. 18 (E)). Next, while changing the front and rear row tube replacement arms 96 and 97 from one row to the staggered arrangement, the tube replacement bar 76 is positioned at the forward end, and the tube replacement bar 76 is lowered to move the empty bobbin wheels 5a and 5b of the roving frame 1 above. Insert the empty bobbin EB (Fig. 18 (F)). Next, the pipe replacement bar 76 is retracted to the retracted end, and the front and rear row pipe replacement arms 96 and 97 are rearranged from the staggered arrangement to the single row arrangement (FIG. 18 (G)). Next, the empty bobbin peg bar 19 at the completion position S5 of the lower transfer position is raised to the standby position S7 and retracted, and the intermediate stop position S3 is reached.
The full bobbin peg bar 18 which was present is lowered to the preparation position S1 of the lower delivery position (FIG. 18 (H)).

When one tube changing operation is completed in this way, the tube changing machine AD moves to the next tube changing position. At this time, the contact Pi (1 pitch feed signal) of the circuit 201 shown in FIG. 17 is closed and the relay RTP is turned on. Turns on. Then, the contact RTP-1 of the circuit 208 is turned off and the solenoid SOL of the solenoid valve of the cylinder 130 is switched,
When the cylinder 130 moves forward and the catcher 129 swings upward, it disengages from the first indexing positioning pin 127, and when the limit switch LSA is turned on at the forward end of the cylinder 130, the relay RLSA is turned on and the circuit 202 contact RLSA-1 is O
N, the relay RMP is turned ON, and accordingly the contacts RMP-1 and RMP-2 of the controller SPC of the circuit 209 are turned ON, the drive motor 124 is normally rotated at a low speed, and the carrier tool 118 is moved in the direction of arrow B in FIG. To move. Next, when the second indexing positioning pin 127 is confirmed by the proximity switch PX, the proximity switch contact PX of the circuit 203 is turned on and the relay RPX is turned on (at this time, the contact Pi is turned off), the circuit. Contact point RPX-1 of 201 is OF
F, relay RTP is also OFF, circuit 204 RPX-2 is ON, timer TR
Turns on. Then, the contact RTP-1 of the circuit 208 is turned ON, the solenoid SOL is switched, the cylinder 130 is retracted, the cutter 129 is lowered, and the transport tool ream 118 moves at a low speed during this time, and the second indexing that has moved. The catcher 129 catches the positioning pin 127, and the drive motor 124 is normally rotated by the timer TR for a predetermined time to ensure that the indexing positioning pin 127 is pressed against the front end of the catcher 129. When timer TR times out, timer contacts TR-1 and TR-2 are turned off
Then, the relays RMP and RPX are turned off, the timer TR is reset, the drive motor 124 is stopped, and as a result, the transport tool station 118 moves by one pitch P4, and as shown in FIG. The second pipe replacement center CL coincides with the second pipe replacement center CL1, L2 of the roving machine 1 and the conveyer station 118, and the second pipe replacement center is started.
When the above operations are repeated and the tube change for one roving machine 1 is completed, the contact Hi is closed in the circuit 205 and the relay RTH is ON and the contact RTH is in order to transfer the transfer device station 118 to the spinning machine side at high speed.
-1 turns OFF, solenoid SOL switches, cylinder 130 for catcher 129 moves forward, catcher 129 rises, forward limit switch LSH turns ON, relay RLSA
Is ON, the relay RMH is ON, the contacts RMH-1, RMH-2 connected to the controller of the circuit 209 are closed, and the contact RTHR-2 is closed at this time, so that the drive motor 124 rotates at high speed. Conveyor equipment chain that holds one full bobbin FB for one spinning machine
118 is conveyed to the spinning machine creel.

As shown in FIG. 18 (A) or (H) of this operation explanatory view, a sufficient vertical gap is generated between the lower end of the bobbin hung on the conveyor 118 and the upper end of the pipe changer AD. Therefore, as shown in FIG. 12, in a portion CP where the transport rails 110 and 111 and the traveling rail 15 of the pipe changer AD intersect in a plan view, the transport tool station 118 and the pipes just hanging the bobbin are connected. Even if the changer AD overlaps in a plane, it does not overlap in the vertical direction.Therefore, a transport rail and a changer in the factory are installed or a changer is installed and moved along the side of the roving machine. The layout of the rail 136 (Fig. 12) becomes easy.

In this embodiment, since the staggered arrangement of the roving machine is made into the bobbin arrangement of the creel of the spinning machine (one row) only by the doffing operation of the pipe changer, when carrying the doffed full bobbin to the spinning machine. The post-processing of can be simplified.

Further, in the present embodiment, the description has been given with the transport tool arranged in one line at the pitch of the spinning frame creel, but the present invention is not limited to this, and the most preferable arrangement for transporting to the spinning frame creel (for example, the zigzag of the spinning frame). Arrangement as it is, or although it is zigzag, the front and back, left and right spacing between each bobbin is changed appropriately)
However, if the zigzag arrangement of the roving machine is still possible, the front and rear of the pipe replacement bar, the left and right of the pipe replacement arm for the rear row, and the front and rear interval changing device may be omitted. Further, in the present embodiment, when the full and empty bobbin peg bars are respectively raised toward the upper delivery position, the upward movement is used to move further upward with respect to the slide block or the elevating block respectively ascending. Therefore, the actual rising end of the slide block and the lifting block is lower than the upper delivery position of each peg bar, which allows the height of the pipe changer body to be lowered.

In the present embodiment, the full bobbin peg bar is lifted from the preparation position to the receiving position at the lower delivery position to place the full bobbin on the full bobbin peg bar.
The full bobbin peg bar may be stopped at the receiving position of the lower delivery position, and the pipe replacement bar may be moved up and down to pass the full bobbin onto the full bobbin peg bar. Further, the transfer device of the series of transfer tools may be a conventionally known battery car. Further, the front and rear row delivery arms are not limited to those of this embodiment, but may be those using a screw feed mechanism or cylinders as shown in Japanese Patent Application No. 58-250963. Further, although the lifting device for empty bobbins has been described using the chain and the chain sprocket, it may be driven by a belt. Further, in the present embodiment, the description has been made on the assumption that the pipes are replaced by four spindles, but the bobbin wheel arrangement of the roving machine may process an appropriate number of spindles at one time.

As described above, according to the present invention, the bobbin for full bobbin and the peg bar for empty bobbin is received by the lifting and lowering device between the tube support and the tube changer that can move and stop along the front surface of the roving frame. Equipped with a common lower delivery position that delivers the bobbin between the upper delivery position and the bobbin wheel, and the full bobbin is taken out from the bobbin wheel onto the peg of the full bobbin peg bar at the common lower delivery position. And a delivery device for supplying an empty bobbin on an empty bobbin peg bar at a common lower delivery position onto the bobbin boil so that the bobbin can be delivered to and from the tube support by the peg bar. Therefore, even if the height of the pipe support is the same as the conventional one, the upper delivery position of the peg bar can be made lower than the height of the pipe support by about the bobbin length. The height of the pipe changer itself can be made lower than the lower end of the bobbin when the bobbin is supported by the pipe support, and the pipe changer can be used stably. As a result, the lower end of the bobbin supported by the pipe support and the upper end of the pipe changer do not overlap with each other in the vertical direction, which facilitates the factory layout of the pipe support and the pipe changer. Furthermore, even if it has the above effects,
Since it is a wagon type pipe changer, it is possible to change the pipes of a plurality of rovings with a single pipe changer, and moreover, since the doffing is directly carried out to the pipe support above the roving frame, once it is placed on the front side of the roving frame. It is easier to connect to a spinning creel than a conventional device that lifts it onto a peg conveyor and then transfers it again to the pipe support of the ceiling rail connected to the subsequent process (spinning machine). You can also operate the bobbin peg bar in parallel,
There is also an advantage that the pipe replacement time can be shortened. Further, according to the present invention, since the lower bobbin peg bar delivery position is common, the control position of the pipe replacement bar of the delivery device for delivering the full bobbin with the bobbin rail is set at three positions (forward end). And an intermediate position corresponding to the retracted end and the lower delivery position), the delivery device can be easily controlled, and the operating space in the front-rear direction required by the delivery device can be reduced.

[Brief description of drawings]

FIG. 1 is a side view of a tube changing device for a roving frame, FIG. 2 is a front view of the tube changing device, FIG. 3 is a plan view, FIG. 4 is a side view of a lifting device for a full bobbin peg bar, and FIG. 6 is an operation explanatory view of a full bobbin peg bar, FIG. 6 is a side view of an elevating device for an empty bobbin peg bar, FIG. 7 is a development view taken along line I-I of FIG. 6, and FIG. 8 is an empty bobbin peg bar. Showing the movement locus of Fig. 9, Fig. 9 is a sectional view of the pipe replacement bar, and Fig. 10 is II- of Fig. 9.
II sectional view, FIG. 11 is an operation explanatory view of the front and rear row tube replacement arms,
Figure 12 is a plan view of the conveyor, running rail and roving machine,
FIG. 14 is a plan view of the transfer device, FIG. 14 is a side view of the transfer device and the positioning device, FIG. 15 is a sectional view taken along line III-III of FIG. 14, and FIG.
FIG. 17 is a plan view of a switching device, FIG. 17 is a control circuit of a transfer device and a positioning device, FIG. 18 is an explanatory diagram of a pipe changing operation, and FIG. 19 is a relational diagram of a roving frame, a pipe changing device, and a conveying device. 1 ... Rover, 3 ... Top-supported flyer, 5a, 5b ...
Bobbin wheel, 18, 19 ...... Peg bar for full bobbin, empty bobbin, 20 …… peg, 76 …… replacement bar, 96, 97 ……
Front and rear row tube replacement arm, 111 …… transport rail, 115 …… board,
116 …… Pipe support, 118 …… Conveyor, 119 …… Transfer device, 125 …… Rotating disk, 127 …… Positioning pin, FB …… Full bobbin, ZB …… Empty bobbin, AD …… Replacement machine , CR …… Conveyor, PX …… Detection switch

Claims (2)

[Claims] 1. A bobbin transfer tool having a plurality of tube supports corresponding to each bobbin wheel of the roving machine is arranged above the roving machine provided with an upper support type flyer along a row of bobbin wheels. , The tube changer is arranged along the front of the roving machine so that it can be stopped freely, and the full bobbin on the bobbin wheel and the empty bobbin hung in advance on the tube supporter are sequentially replaced by the tube changer. In the tube changing device of the roving machine, the tube changing machine is provided with peg bars for full bobbins and empty bobbins each having a peg corresponding to the bobbin wheel at the time of changing pipes, and these peg bars are provided with bobbin wheels. Not to interfere with each other during the ascending / descending operation between the common lower transfer position for full and empty bobbin delivery and the upper support position for full / empty bobbin delivery with the pipe support. By lifting device This changer is equipped with a full bobbin upper part on the bobbin wheel to take out the full bobbin onto the peg bar for the full bobbin at the common lower delivery position, and the empty space at the common lower delivery position. A transfer device for a roving machine, comprising a delivery position configured to hold an empty bobbin upper portion on a bobbin peg bar and supply the empty bobbin onto a bobbin wheel. 2. A roving machine is a double-row roving machine in which the supporting flyers are arranged in a zigzag manner, and the transfer device is provided with a pipe replacement bar which can be moved back and forth toward the front of the roving machine and can be moved up and down. The pipe replacement bar is equipped with front and rear row pipe replacement arms that can face the staggered flyer in a state where the pipe replacement machine is stopped at a predetermined pipe replacement position. The pipe changing device for the roving machine according to claim 1, further comprising a device for changing the front-rear and left-right intervals of the rear-row pipe changing arm.