JP2004315027A - Label affixing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a label affixing device capable of enhancing the efficiency of the label affixing work by shortening the time of setting a label tape to the device, and correctly setting the label tape to the device even by a non-skilled worker by simplifying the work of setting the label tape to the device. <P>SOLUTION: The label affixing device comprises a label tape transfer mechanism to continuously transfer a label tape 3 in which a label is temporarily affixed to a surface of a strip-like separator 4, and a peeling unit 22 which is abutted on a back side of an intermediate portion of the separator 4 and returns the label tape 3 to peel the label from the separator 4, and further comprises a peeling unit moving mechanism to reciprocate the peeling unit 22 in the returning direction of the label tape 3. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a label sticking apparatus that peels a label from a band-shaped backing sheet, sticks the label on a conveyed object placed on a belt conveyor or the like, and collects the backing sheet.
[0002]
[Prior art]
2. Description of the Related Art Generally, a device for attaching a label to a product or the like is provided in a product manufacturing factory or a backyard of a retail store. This is because a label tape wound around a paper tube in the form of a roll (the label is temporarily attached to the surface of a band-shaped backing paper) is held on a rotatable holding reel, and the label tape wound in a roll The extending strip-shaped label tape is a device wound around a plurality of rollers and folded back by a peeling unit. According to this device, the label tape is transported in the longitudinal direction of the band-shaped label tape by rotating the roller by a motor or the like, and the label is peeled from the backing paper at the folded peeling portion. By arranging a belt conveyor or the like below the peeling section and continuously transporting the article to be bonded below the peeling section, a label can be attached to the article to be bonded. The end of the backing is hung on a take-up reel, and the backing from which the label has been peeled off is wound up and collected by rotating the take-up reel. (For example, refer to Patent Document 1).
[0003]
[Patent Document 1]
JP-A-63-258738 (page 3-4, FIG. 1)
[0004]
[Problems to be solved by the invention]
However, according to the above-described conventional apparatus, the take-up reel winds up the backing paper by a constant rotation, so that the diameter of the winding backing paper per unit rotation of the take-up reel is larger than when the diameter of the winding backing paper is small. Increases the winding amount. As a result, when the diameter of the winding board becomes large, the mounting sheet is pulled more than necessary beyond the amount of the label tape transported by the rollers, and the label attaching accuracy is reduced.
[0005]
The present invention has been made in consideration of the above problems, and ensures a stable label tape transfer amount by keeping the winding amount per unit rotation constant regardless of the diameter of the winding board. An object of the present invention is to provide a label sticking apparatus that can improve label sticking accuracy.
[0006]
[Means for Solving the Problems]
The invention according to claim 1 is a label sticking apparatus provided with a mount collecting mechanism rotatably having a take-up shaft for winding a strip-shaped mount from which a label has been peeled off, wherein the mount collecting mechanism includes There is provided a take-up rotating section that comes into contact with the outer peripheral surface of the roll-shaped backing material wound on the take-up shaft section, and a take-up section rotating mechanism that rotates the take-up rotating section in the take-up direction of the backing sheet. It is characterized by:
[0007]
With such a feature, when the winding rotating unit rotates, the mount in contact with the winding rotating unit rotates, and the amount of winding of the mount per unit rotation of the winding rotating unit becomes constant.
[0008]
According to a second aspect of the present invention, in the label sticking apparatus according to the first aspect, at least one of the winding shaft portion and the winding rotating portion has the winding shape adapted to a diameter of the roll-shaped mount. An inter-axis distance adjusting mechanism for adjusting an inter-axis distance between the shaft portion and the winding rotating portion is additionally provided.
[0009]
With such a feature, the center distance between the winding shaft portion and the winding rotating portion is adjusted according to the mount winding amount.
[0010]
According to a third aspect of the present invention, in the label affixing device according to the first or second aspect, at least one of the winding shaft portion and the winding rotating portion is moved from a contact position to a non-contact position. A take-up unit moving mechanism for moving the take-up unit to the second position.
[0011]
Due to such a feature, the winding rotary unit is separated from the outer peripheral surface of the mount wound on the winding shaft, so that the mount is easily hooked on the winding shaft and the mount wound on the winding shaft is Easy to take out.
[0012]
According to a fourth aspect of the present invention, in the label sticking apparatus according to the third aspect, the winding unit moving mechanism is at least engaged with a gear that rotates about a fixed shaft, and the winding shaft is meshed with the gear. And a driven meshing member to which one of the winding portion and the winding rotary portion is attached, and a driving meshing member meshed with the gear and formed with a concave portion facing the gear. It is characterized by having.
[0013]
With such a feature, the driven meshing member moves when one of the winding shaft portion and the winding rotating portion moves, and the gear meshed with the driven meshing member rotates. At this time, the recess of the drive meshing member is arranged at a position facing the gear, and the gear does not move because the drive meshing member is not meshed with the gear. Further, by moving the drive meshing member, the concave portion of the drive meshing member is moved, and the gear meshes with the drive meshing member. When the drive meshing member moves in this state, the gear rotates to move the driven meshing member, and one of the winding shaft portion and the winding rotating portion attached to the driven meshing member moves.
[0014]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, first and second embodiments of the label sticking apparatus according to the present invention will be described with reference to the drawings.
[0015]
[First Embodiment]
In FIG. 1, reference numeral 1 denotes a label roll. The label roll 1 is composed of a cylindrical paper tube 2 and a label tape 3 wound in a roll around the paper tube 2 as a core. Is composed of a band-shaped mount 4 and a label 5 temporarily attached to the surface of the mount 4. In FIG. 2, reference numeral 6 denotes a label sticking device 6 for sticking the label 5 shown in FIG. 1 to a not-shown object to be stuck and carried on a belt conveyor or the like (not shown). As shown in FIGS. 1 and 2, a label attaching device 6 continuously transfers a label tape 3 and peels off a label 5 from a backing sheet 4, and holds a label roll 1 rotatably and a label. And a label tape supply mechanism 8 for continuously feeding the tape 3. 2 is a diagram showing one side surface of the label sticking device 6, in which the left-right direction in FIG. 2 is the front-back direction of the label sticking device 6, and the depth direction in FIG. 2 is the width direction of the label sticking device 6.
[0016]
First, the configuration of the label attaching device main body 7 will be described.
[0017]
As shown in FIG. 2, a polygonal frame substrate 9 is vertically arranged, and the frame substrate 9 is provided with rails 10 extending diagonally. On one side (front side in FIG. 2) of the frame substrate 9, a front plate 11 facing a lower front part of the frame substrate 9 and a rear plate 12 facing a rear upper part of the frame substrate 9 are parallel to the frame substrate 9. Are located in The front plate 11 and the rear plate 12 are provided with rails 10 facing the rails 10 provided on the frame substrate 9, respectively.
[0018]
Between the center part of the frame substrate 9 and the rear part of the front plate 11, a transfer rotating part 13 composed of a cylindrical roller extending in the width direction of the label sticking device 6 is interposed at the top and bottom with the rail 10 interposed therebetween. . The upper transfer rotating unit 13a above the rail 10 is formed of a roller having a larger diameter than the lower transfer rotating unit 13b below the rail 10. The transfer rotating unit 13 has a configuration in which a friction member 15 having a large friction coefficient is coated on an intermediate portion of the round bar-shaped shaft members 14a and 14b, and one ends of the shaft members 14a and 14b are provided on the frame substrate 9. The other end is inserted through a not-shown through-hole, and the other end is rotatably attached to the front plate 11.
[0019]
FIG. 3 is a view showing the other side surface of the label sticking device 6. As shown in FIG. 3, an upper transfer rotating unit gear 16 is provided at one end of the shaft of the upper transfer rotating unit 13 a, A lower transfer rotating unit gear 17 is provided at one end of the shaft of the transfer rotating unit 13b. A drive gear 19 that is rotated by a drive source 18 such as a motor is meshed with the upper transfer rotating unit gear 16 and the lower transfer rotating unit gear 17, respectively. A transfer rotation mechanism 20 configured to rotate the transfer rotation unit 13 including the upper transfer rotation unit 13 and the lower transfer rotation unit 13 by the upper transfer rotation unit gear 16, the lower transfer rotation unit gear 17, the drive gear 19, and the drive source 18 is configured. Have been. A label tape transfer mechanism 21 that continuously transfers the band-shaped label tape 3 is configured by the transfer rotation unit 13 and the transfer rotation mechanism 20 described above.
[0020]
As shown in FIGS. 2 and 4, between the rails 10 provided on the frame substrate 9, the front plate 11, and the rear plate 12 and facing each other, a peeling portion 22 made of a rectangular plate inclined forward is interposed. ing. A sliding portion (not shown) is provided on both side surfaces of the peeling portion 22 to be inserted and moved on the rail 10, and the peeling portion 22 is provided movably back and forth along the rail 10. An acute angle portion 22a is formed at the front end of the peeling portion 22, and the acute angle portion 22a is bent upward. Behind the peeling section 22, two brackets provided with rotatable guide rollers 23 extending in the width direction of the label attaching device 6 and abutting on the lower transport rotating section 13 are provided on both sides of the rear section of the peeling section 22. 24 are provided. At the tips of the two brackets 24, elongated holes 24a are provided in the vertical direction, and pin members 23a projecting from both ends of the guide roller 23 are inserted into the elongated holes 24a. I have.
[0021]
On the lower surface of the peeling section 22, a peeling section moving rack 25 extending in the moving direction of the peeling section 22 is provided. Peeling part moving gears 26a and 26b meshed with the peeling part moving rack 25 are rotatably interposed between the frame substrate 9 and the front plate 11 and between the frame substrate 9 and the rear plate 12, respectively. The shaft members 27a and 27b are inserted through the separation portion moving gear 26, respectively. Between the frame substrate 9 and the front plate 11, a shaft member 27a of the front peeling portion moving gear 26a is interposed, and one end of the front peeling portion moving gear 26a is inserted into a through hole (not shown) provided in the frame substrate 9 respectively. The other end is rotatably attached to the front plate 11. A rear peeling portion moving gear 26b is interposed between the frame substrate 9 and the rear plate 12, and one end of a shaft 27b of the rear peeling portion moving gear 26b is inserted into a through hole (not shown) provided in the frame substrate 9 respectively. The other end is rotatably attached to the rear plate 12, respectively.
[0022]
As shown in FIGS. 2 and 3, one end of the shaft member 27b of the front peeling part moving gear 26a is provided with a front peeling part moving gear gear 28a, and one end of the shaft material 27b of the rear peeling part moving gear 26b. The section is provided with a rear peeling section moving gear gear 28b. The front peeling section moving gear gear 28a is provided with a clutch mechanism 29 for switching power transmission when the peeling section 22 moves to a predetermined position in front. A sensor (not shown) for switching on and off is connected to the clutch mechanism 29. A sensor (not shown) is provided in a pair at the front part of the peeling part 22 and the frame substrate 9, and when the peeling part 22 moves forward, the clutch mechanism 29 is switched off. Further, a sensor (not shown) is connected to the drive source 18, and the drive source 18 is turned off when the peeling unit 22 moves forward.
[0023]
Between the front peeling section moving gear gear 28a and the driving gear 19, a first belt 30 meshed with the front peeling section moving gear gear 28a and the driving gear 19 is wound. A second belt 31 meshed with the front peeling section moving gear gear 28a and the rear peeling section moving gear gear 28b is wound between the gear 28a and the rear peeling section moving gear gear 28b. The front peeling section moving gear 26a, the rear peeling section moving gear 26b, the peeling section moving rack 25, the front peeling section moving gear gear 28a, the rear peeling section moving gear gear 28b, the driving gear 19, the driving source 18, the first belt 30, and the The two belts 31 constitute a peeling part moving mechanism 32 that moves the peeling part 22 in the front-rear direction.
[0024]
As shown in FIGS. 2 and 4, a label tape pressing member 33 made of a long material extending in the width direction of the label attaching device 6 is provided between the front portion of the frame substrate 9 and the front portion of the front plate 11. It is interposed above the rail 10. At the rear of both ends of the label tape pressing member 33, there are provided rotating shafts 34 rotatably attached to the frame substrate 9 and the front plate 11, respectively. A curved surface 33a inclined in the direction is formed. On the lower surface of the label tape pressing member 33 and on the upper surface of the front part of the peeling part 22, a pair of label identifying means 35 for identifying the mount 4 and the label 5 according to the state of light transmission are provided.
[0025]
As shown in FIG. 2, between the center of the frame substrate 9 and the lower end of the rear plate 12, a take-up rotating unit 36 composed of a cylindrical roller extending in the width direction of the label attaching device 6 is provided below the rail 10. Has been interposed. The winding rotating section 36 is for rotating the roll-shaped backing material 4 wound around a winding shaft section 44, which will be described later, and the intermediate portion of the round rod-shaped shaft member 37 is coated with a friction material 38 having a large friction coefficient. It consists of a configuration. One end of the shaft member 37 of the winding rotation unit 36 is inserted into a through hole (not shown) provided in the frame substrate 9, and the other end is rotatably attached to the rear plate 12. A round rod-shaped support rod 39 extending in the width direction of the label attaching device 6 is interposed between the rear portion of the frame substrate 9 and the upper end of the rear plate 12.
[0026]
As shown in FIG. 3, a take-up rotating unit gear 40 is provided at one end of the shaft member 37 of the take-up rotary unit 36, and a driven gear 41 is provided on the outer surface of the rear upper end of the frame substrate 9. It is provided rotatably. A third belt 42 meshed with the winding rotary unit gear 40, the driving gear 19, and the driven gear 41 is wound between the winding rotary unit gear 40, the driving gear 19, and the driven gear 41. I have. A winding unit rotating mechanism 43 configured to rotate the winding rotating unit 36 by the winding rotating unit gear 40, the driving gear 19, the driven gear 41, the driving source 18, and the third belt 42 is configured.
[0027]
As shown in FIG. 2, a winding shaft 44 extending in the width direction of the label attaching device 6 is disposed obliquely rearward of the winding rotating unit 36. The winding shaft portion 44 is configured by rotatably inserting a round bar-shaped shaft member 45 around the center shaft of a hollow cylindrical winding roller, and the circumferential surface of the winding shaft portion 44 is shown in the axial direction. A not-shown cut is formed. As shown in FIG. 5, one end of the shaft member of the winding shaft portion 44 is fixed to a rear end of a long rod-shaped arm member 46 extending rearward. A driven meshing member 47 formed of a rack is joined to the arm member 46 in parallel, and one end of a biasing member 49 such as a spring is joined to the arm member 46 via a mounting pin 48 projecting from the arm member 46. The other end of the urging member 49 is fixed to the frame substrate 9. In the vicinity of the driven meshing member 47, a drive meshing member 50 composed of a rack facing the driven meshing member 47 is arranged in parallel with the driven meshing member 47 at an interval. A rotatable gear 51 is interposed between the driving meshing member 50 and the driven meshing member 47, and the gear 51 is meshed with the driven meshing member 47. The drive meshing member 50 has a recess 50a facing the gear 51, and the drive meshing member 50 is provided with a motor (not shown) for moving the drive meshing member 50 in the axial direction.
[0028]
The winding shaft 44 moves the winding shaft 44 rearward by the gear 51, the driven meshing member 47, and the urging member 49, so that the inter-axis distance between the winding shaft 44 and the winding rotating unit 36 is increased. Is adjusted. Further, the winding shaft 44 is moved by the gear 51, the driving meshing member 50, the driven meshing member 47, the urging member 49, and a motor (not shown) so that the mount 4 and the winding rotating unit 36 are wound around the winding shaft 44. The take-up part moving mechanism 53 is configured to move and separate from a contact position where the take-up part 44 contacts the base material 4 wound around the take-up shaft part 44 and a non-contact position where the take-up rotating part 36 does not contact. The above-mentioned winding shaft 44, winding rotating unit 36, winding unit rotating mechanism 43, inter-axis distance adjusting mechanism 52, and winding unit moving mechanism 53 wind the band-shaped mount 4 from which the label 5 has been peeled off. A collection mechanism 54 is configured.
[0029]
As shown in FIG. 2, an operation switch 55 connected to the drive source 18 via a control panel (not shown) is provided on the outer surface of the rear plate 12. The operation switch 55 is connected to a motor (not shown) that moves the drive meshing member 50 shown in FIG. 5 in the axial direction via a control panel (not shown).
[0030]
Next, the configuration of the label tape supply mechanism 8 will be described.
[0031]
As shown in FIG. 2, a substantially triangular bucket substrate 56 is arranged above the frame substrate 9 in parallel with the frame substrate 9. On the side of the bucket board 56, two rectangular bucket plates 57 facing the bucket board 56 are arranged so as to be symmetrical in an inverted C-shape in side view. A locked portion 58 into which the support rod 39 provided between the rear portion of the frame substrate 9 and the upper end portion of the rear plate 12 is formed on the lower end surfaces of the bucket substrate 56 and one bucket plate 57. ing.
[0032]
As shown in FIGS. 6 and 7, between the upper end portions of the bucket board 56 and the upper end portions of the two bucket plates 57, and between the middle end portions of the bucket board 56 and the middle portion of the two bucket plates 57. The support portions 59 extending in the width direction of the label attaching device 6 and supporting the label roll 1 are interposed therebetween. The support portion 59 is formed of a hollow cylindrical support roller 60 having a large friction coefficient, and a round shaft 61 is rotatably inserted through the center axis of the support roller 60. One end of the shaft member of the support portion 59 is rotatably attached to the bucket substrate 56, and the other end is rotatably attached to the bucket plate 57. A round rod-shaped rod member 62 is fixed between the support portion 59 provided at the upper end of the bucket plate 57 and the support portion 59 provided in the middle in parallel with the support portion 59.
[0033]
Between the lower end of the bucket substrate 56 and the lower end of the two bucket plates 57, there are interposed feed rotating parts 63 extending in the width direction of the label sticking device 6. The two feed rotation parts 63 are configured such that a middle part of a round bar-shaped shaft member 64 is coated with a friction material 65 having a large friction coefficient, and one end of the shaft member 64 is provided on a bucket substrate 56. The other end is inserted through a not-shown through hole, and the other end is rotatably attached to the bucket plate 57. The label roll 1 is disposed above the support portion 59 and the sending-out rotating portion 63 such that both end faces face the bucket substrate 56 and the bucket plate 57 that face each other.
[0034]
As shown in FIG. 3, a delivery rotating unit gear 66 is provided at one end of a shaft member 64 of each of the two delivery rotating units 63, and the delivery rotating unit is driven above the delivery rotating unit gear 66 at the rear. A gear 67 is rotatably mounted on the outer surface of the bucket plate 57. The delivery rotating section driven gear 67 meshes with a delivery rotating section rotation pinion gear 68 rotatably attached to the outer surface of the bucket plate 57. The output rotation unit rotation pinion gear 68 is meshed with the driven gear 41 of the label sticking device main body 7. A fourth belt 69 that is meshed with the two transmission rotation unit gears 66 and the transmission rotation unit driven gear 67 is wound between the two transmission rotation unit gears 66 and the transmission rotation unit driven gear 67. I have. The two sending rotation unit gears 66, the sending rotation unit driven gear 67, the sending rotation unit rotation pinion gear 68, the fourth belt 69, the driven gear 41, the take-up rotation unit gear 40, the drive gear 19, the drive source 18, and the third belt A delivery rotation mechanism 70 for rotating the delivery rotation unit 63 in the direction in which the label roll 1 feeds the label tape 3 is configured by 42.
[0035]
Also, as shown in FIGS. 2, 6, and 7, two positioning plates 71 are provided between the opposing bucket substrates 56 and the bucket plates 57 in parallel with the bucket substrates 56 with an interval in the width direction. The two positioning plates 71 are in contact with both end surfaces 1 a of the label roll 1. A rod material 62 is inserted into one end of the positioning plate 71, and the positioning plate 71 is provided so as to be rotatable upward about the rod material 62 and to be movable in the width direction of the label attaching device 6. . At the lower portion of the positioning plate 71, an uneven portion into which the support portion 59 and the sending rotation portion 63 are fitted is formed. The positioning plate 71, the support portion 59, the sending rotation portion 63, the bucket substrate 56, and the bucket plate 57 constitute a receiving portion 72 that supports the label roll 1 from below.
[0036]
As shown in FIG. 7, between the two positioning plates 71, two racks 73 provided with teeth on surfaces facing each other extend in the width direction of the label attaching device 6. A pinion 74 having teeth on the outer peripheral surface is interposed between the two racks 73, and the two racks 73 and the pinion 74 are meshed with each other. One rack 73 is fixed to one positioning plate 71, and the other rack 73 is fixed to the other positioning plate 71. The pinion 74 is rotatably attached to the rod member 62.
[0037]
Next, a method of using the label sticking apparatus having the above-described configuration will be described.
[0038]
First, as shown in FIG. 2, the label attaching device main body 7 is arranged on a device for carrying an object to be attached, such as a belt conveyor (not shown), and a locked portion provided on the bucket substrate 56 and the bucket plate 57. The label tape supply mechanism 8 is arranged on the label sticking device main body 7 by fitting the 58 into the support rod 39 of the label sticking device main body 7. Next, as shown in FIG. 2, the receiving portion 72 is opened by rotating the positioning plate 71 upward, and the label roll 1 is placed on the support portion 59 of the receiving portion 72 and the sending-out rotating portion 63. Then, the positioning plate 71 is rotated downward to close the receiving portion 72, and one of the positioning plates 71 is brought into contact with one end surface 1 a of the label roll 1. As shown in FIG. 7, when one positioning plate 71 is moved, one rack 73 fixed to one positioning plate 71 is moved to rotate the pinion 74. As the pinion 74 rotates, the other rack 73 moves, and the other positioning plate 71 moves symmetrically with the one positioning plate 71, and comes into contact with the other end surface 1 a of the label roll 1.
[0039]
Next, the label tape 3 of the label roll 1 set in the label tape supply mechanism 8 is pulled out from between the two sending rotation units 63 (sending port), and the leading end of the label tape 3 is taken up with the transfer rotating unit 13. It is passed through the rotating part 36, is hooked on a not-shown cut of the winding shaft part 44, and is attached to the winding shaft part 44. As the take-up shaft 44 rotates, the label tape 3 is wound with the upper end in contact with one (the left side in FIG. 2) sending-out rotating section 63 and the lower end in contact with the take-up rotating section 36. At this time, the peeling section 22 is moved to a rear position that does not interfere with the label tape 3.
[0040]
Next, as shown in FIG. 2 and FIG. 3, the operation source 55 is operated by operating the operation switch 55, and the driving gear 19 is rotated in the direction of the black line arrow in FIG. As the drive gear 19 rotates, the first belt 30 moves in the direction of the dashed line arrow in FIG. 3, and the front peeling section rotating gear 28a meshed with the first belt 30 rotates in the direction of the black line arrow. . The rotation of the front peeling section rotating gear 28a causes the second belt 31 to move in the direction of the dashed line arrow, and the rear peeling section rotating gear 28b to rotate in the direction of the black line arrow. By rotating the front peeling section rotating gear 28a and the rear peeling section rotating gear 28b, the shaft members 27a and 27b rotate, and the front peeling section moving gear 26a and the rear peeling section moving gear 26b rotate.
[0041]
The peeling part 22 having the peeling part moving rack 25 meshed with the rear peeling part moving gear 26b advances to the middle part of the frame substrate 9 by the rotation of the rear peeling part moving gear 26b, and the rotating front peeling part moving gear The peeling unit moving rack 25 meshes with 26a. The peeling section 22 is further moved forward by the rotation of the front peeling section moving gear 26 a, and the acute angle portion 22 a at the tip comes into contact with the curved surface 33 a of the label tape pressing member 33. As shown in FIG. 4, the acute angle portion 22 a in contact with the curved surface 33 a of the label tape pressing member 33 presses the curved surface 33 a of the label tape pressing member 33 as the peeling portion 22 advances. The rotatable label tape pressing member 33 rotates upward about the rotation shaft 34, and the peeling portion 22 advances while sliding the acute angle portion 22 a on the curved surface 33 a of the label tape pressing member 33.
[0042]
As shown in FIGS. 2 and 3, when the drive gear 19 rotates in the direction indicated by the black arrow, the upper transfer rotation unit gear 16 and the lower transfer rotation unit gear 17 meshed with the drive gear 19 become black lines. Each rotates in the direction of the arrow. The rotation of the upper transfer rotating unit gear 16 and the lower transfer rotating unit gear 17 causes the respective shaft portions 14a and 14b to rotate, thereby rotating the upper transfer rotating unit 13a and the lower transfer rotating unit 13b.
[0043]
Further, as the drive gear 19 rotates, the third belt 42 meshed with the drive gear 19 moves in the direction of the dashed line arrow, and the take-up rotating gear 40 and the driven gear 41 meshed with the third belt 42. Rotate in the directions of the black arrows. When the take-up rotation unit gear 40 rotates, the shaft 37 of the take-up rotation unit 36 rotates, and the take-up rotation unit 36 rotates. Further, as the driven gear 41 rotates, the delivery rotating portion pinion gear 68 meshed with the driven gear 41 rotates in the direction of the black arrow, and the delivery rotating portion driven gear 67 meshed with the delivery rotating portion pinion gear 68. Rotates in the direction of the black arrow. The rotation of the output rotation unit driven gear 67 causes the fourth belt 69 meshed with the output rotation unit driven gear 67 to move in the direction of the dashed line arrow, and the two transmission rotation unit gears meshed with the fourth belt 69. 66 rotate in the direction of the black line arrow, respectively. As the two sending rotary unit gears 66 rotate, the shaft members 64 of the sending rotary unit 63 rotate, and the two sending rotary units 63 rotate.
[0044]
When the peeling unit 22 moves forward, the peeling unit 22 presses the label tape 3 wound between the sending rotation unit 63 and the winding rotation unit 36, and sets the acute angle portion 22a as a turning point so that the label tape 3 Turn back the middle part of. At this time, the label tape 3 moves forward by the pressing of the peeling unit 22, the sending rotary unit 63 sends out the label tape 3 by rotation, and the upper transport rotating unit 13a and the lower transport rotating unit 13b transport the label tape 3 by rotating. I do.
[0045]
When the peeling unit 22 moves to a predetermined front position, the driving source 18 is turned off by a sensor (not shown), and the front peeling unit moving gear 26a, the rear peeling unit moving gear 26b, the sending rotary unit 63, and the upper transport rotating unit 13a. Then, the rotations of the lower transfer rotating unit 13b and the winding rotating unit 36 are stopped. Further, when the peeling section 22 moves to a predetermined front position, the clutch mechanism 29 provided on the front peeling section moving gear gear 28a is turned off, and the power is not transmitted to the front peeling section moving gear gear 28a.
[0046]
Next, the operation switch 55 is operated again to operate the drive source 18, and the drive gear 19 is rotated in the direction of the black line arrow in FIG. When the drive gear 19 rotates, the upper transfer rotating unit gear 16, the lower transfer rotating unit gear 17, the take-up rotating unit gear 40, and the delivery rotating unit gear 66 rotate as in the case described above, and the upper transfer rotating unit 13a, The lower transport rotation unit 13b, the winding rotation unit 36, and the delivery rotation unit 63 rotate.
[0047]
When the sending-out rotating unit 63 rotates in contact with the label roll 1, the label roll 1 rotates in the feeding direction of the label tape 3 (a counterclockwise direction in FIG. 2), and the label tape wound in a roll shape. Send 3 out. The sent label tape 3 is transferred in the direction of the acute angle portion 22a of the peeling portion 22 by rotating the upper transfer rotating portion 13a which comes into contact with the surface of the label tape 3. As shown in FIG. 4, the peeling section 22 folds an intermediate portion of the label tape 3 being transported by the acute angle section 22a. Since the rigidity of the mount 4 itself is greater than the adhesive force of the temporary attachment of the mount 4, the label 5 cannot separate from the turn of the mount 4 and peels off from the mount 4. The peeled-off label 5 adheres to an object (not shown) which is carried and carried on a belt conveyor (not shown).
[0048]
Further, as shown in FIG. 2, by rotating the lower transfer rotating unit 13 b that comes into contact with the surface of the mount 4, the mount 4 from which the label 5 has been peeled is transferred in the direction of the winding shaft 44. When the winding rotating unit 36 that contacts the mount 4 wound around the winding shaft 44 rotates, the winding shaft 44 rotates to wind the mount 4. As shown in FIGS. 5 and 8, the urging member 49 constantly urges the winding shaft 44 in the direction of the winding rotating unit 36, and the winding rotating unit 36 winds the winding shaft 44. Is in contact with the mounted backing sheet 4. Since the gear 51 with which the driven meshing member 47 is meshed is rotatable and the driven meshing member 47 is movable, the gear 51 is attached to the arm member 46 fixed to the driven meshing member 47 via the shaft 45. In the winding shaft 44, the diameter of the mount 4 wound around the winding shaft 44 increases, and the winding shaft 44 moves away from the winding rotating unit 36.
[0049]
Next, when the label roll 1 is replaced or the adhered object is interrupted, the operation switch 55 is operated again to stop the operation of the drive source 18 and stop the rotation of the drive gear 19. When the rotation of the driving gear 19 stops, the rotations of the upper transfer rotation unit gear 16, the lower transfer rotation unit gear 17, the winding rotation unit gear 40, and the delivery rotation unit gear 66 stop, and the upper transfer rotation unit 13a, the lower transfer rotation unit 13b, the rotation of the winding rotation unit 36 and the rotation of the sending rotation unit 63 are stopped.
[0050]
Next, by operating the operation switch 55, a motor (not shown) is operated to move the drive meshing member 50 in the axial direction (the direction of the dashed line arrow in FIG. 5). When the drive meshing member 50 moves, the concave portion 50a facing the gear 51 moves, and the drive meshing member 50 meshes with the gear 51. When the drive meshing member 50 meshed with the gear 51 moves, it rotates in the direction of the solid arrow, and the driven meshing member 47 meshed with the gear 51 moves in the direction of the dashed-dotted arrow. When the driven meshing member 47 moves, the winding shaft 44 attached to the arm member 46 fixed to the driven meshing member 47 via the shaft 45 makes contact between the winding rotating unit 36 and the mount 4. From the position, it moves to a non-contact position where there is an interval between the winding rotating unit 36 and the mount 4. The roll-shaped backing sheet 4 at the non-contact position is taken out from the winding shaft 44 and disposed.
[0051]
By the way, as shown in FIG. 4, a pair of label identifying means 35 provided on the lower surface of the label tape pressing member 33 and the upper surface of the front part of the peeling part 22 are provided with a light transmitting condition when the label tape 3 passes therebetween. To identify the mount 4 and the label 5 and send a signal to the drive source 18 via a control panel (not shown). The drive source 18 receives the signal and adjusts the amount of the label tape 3 to be sent, the amount to be transferred, and the amount to be wound.
[0052]
According to the label pasting device 6 having the above-described configuration, since the peeling section 22 is moved in the front-back direction of the label pasting apparatus 6 by the peeling section moving mechanism 32, the space between the label tape supply mechanism 8 and the winding shaft section 44 is formed. The label tape 3 wound around is folded back by moving the peeling section 22 disposed rearward forward, and the label tape 3 is set in the label attaching device 6. Thus, the time for setting the label tape 3 on the label sticking device 6 can be reduced, and the work efficiency of the label sticking operation can be improved. Further, by simplifying the operation of setting the label tape 3 on the label attaching device 6, even an unskilled worker can set the label tape 3 accurately.
[0053]
In addition, a label tape pressing member 33 that presses the label tape 3 against the peeling portion 22 is provided in front of the folded portion of the label tape 3, so that the label tape 3 is prevented from floating at the folded portion and the label tape 3. Is prevented from coming off the peeling section 22 during the transfer. As a result, the label 5 is reliably peeled off from the backing sheet 3, and the label 5 can be attached even when the backing sheet 3 is made of hard paper. Further, the label tape 3 is less likely to come off from the peeling portion 22, and the setting of the label tape 3 again can be reduced.
[0054]
Further, a pair of label identifying means 35 for identifying the mount 4 and the label 5 is provided on the lower surface of the label tape pressing member 33 and the upper surface of the front part of the peeling portion 22, so that the label tape 3 is pressed against the peeling portion. At the same time, the transfer of the label tape 3 is adjusted according to the temporary attachment interval of the label 5 temporarily attached to the mount 4 and the size of the label 5. Thus, when the label tape 3 is replaced with a different type, it is not necessary to set the transfer amount of the label tape 3 per label 5, and the operation of replacing the label tape 3 with the label tape 3 can be simplified.
[0055]
Further, since an acute angle portion 22a that is bent upward is formed on the contact surface of the peeling portion 22 that contacts the rear surface of the intermediate portion of the backing paper 4, the intermediate portion of the label tape 3 is sharply folded by the acute angle portion 22a. The inclination angle of the label 5 to be peeled and peeled is adjusted. This makes it easier for the label 5 to be peeled off from the backing sheet 4 and allows the label 5 to be stuck even when the sticking surface of the object to which the label 5 is stuck is inclined. Further, since the label tape pressing member 33 is rotatably provided and has a curved surface 33a at the lower end surface, the label tape pressing member 33 rotates when the acute angle portion 22a comes into contact with the curved surface 33a. It rotates upward about the axis 34. Thereby, even if the acute angle portion 22a interferes with the label tape pressing member 33, the peeling portion 22 can move forward.
[0056]
In addition, the label tape 3 is sent out by rotating the sending-out rotating unit 63 that comes into contact with the outer peripheral surface of the label roll 1 and is transported by rotating the transporting rotating unit 13 that comes into contact with the label tape 3. Regardless of the weight of 1, the load on the transfer rotation mechanism 20 that rotates the transfer rotation unit 13 is always constant, and the delivery amount and the transfer amount are proportional. As a result, a change in the sticking accuracy of the label 5 caused by the weight of the label roll 1 that decreases as the label tape 3 is sent out can be suppressed, and stable sticking accuracy can be secured. Further, when the rotation of the sending rotation unit 63 stops, the sending of the label tape 3 is forcibly stopped, so that the label tape 3 is sent out by inertia and the label tape 3 can be prevented from being loosened. Incidentally, when the label roll 1 is rotatably arranged and the label tape 3 is sent out by being pulled by the transfer rotation mechanism 20, the load on the transfer rotation mechanism 20 changes depending on the weight of the label roll 1, and the transfer rotation mechanism 20 Is stopped, the label roll 1 is rotated by inertia, and the label tape 3 is loosened.
[0057]
Further, since the label tape 3 is supported from below by the receiving portion 72, even when the diameter of the label roll 1 is reduced, the outer peripheral surface of the label roll 1 comes into contact with the sending-out rotating portion 63. As a result, even if the label tape 3 is sent out and the diameter of the label roll 1 is reduced, the label roll 1 can rotate without moving the position of the sending-out rotation unit 6. Further, since the label roll 1 is supported from below, there is no need to pass the paper tube 2 of the label roll 1 through a shaft, and the label roll 1 is set on the label tape supply mechanism 8 simply by being placed on the receiving portion 72. As a result, the time required for setting the label roll 1 is reduced, and the operation is simple, so that even an unskilled worker can set the label roll.
[0058]
The delivery rotation mechanism 70 for rotating the delivery rotation unit 63 and the transport rotation mechanism 20 for rotating the transport rotation unit 13 are driven by the drive source 18, so that the label rotation of the label tape 3 by the delivery rotation unit 63 and the transportation rotation unit 13 are performed. The transfer of the label tape 3 is interlocked. As a result, the output amount of the label tape 3 is proportional to the transfer amount, so that the output amount of the label tape 3 is larger than the transfer amount and the label tape 3 is loosened, and the output amount of the label tape 3 is smaller than the transfer amount. The tape 3 is not pulled, so that the accuracy of attaching the label 5 can be improved.
[0059]
Since the sending rotary unit 63 is provided in a pair with the outlet of the label tape supply mechanism 8 through which the label tape 3 is sent out, the sending rotary unit 63 is rotated in the reverse direction to rotate the label roll 1 in the reverse direction, and the label tape 3 is rotated. It is possible to send out. Thus, the label roll 1 of the label tape 3 in which the label 5 is temporarily attached to the back surface of the mount 4 can be used.
[0060]
Since the frictional members 15 and 65 are coated on the surfaces of the sending rotation unit 63 and the transfer rotation unit 13 that are in contact with the label tape 3, the label tape 3 and the delivery rotation unit 63 or the label tape 3 and the transfer rotation unit 13 The frictional force of the label tape 3 increases, and the label tape 3 is prevented from spinning when it is sent, transferred or stopped. As a result, the label tape 3 can be reliably sent and transferred, and the rotation of the label roll 1 can be reliably stopped to stop sending the label tape 3, and the transfer of the label tape 3 can be stopped.
[0061]
In addition, two racks 73 and pinions 74 respectively meshed with the two racks 73 are provided on the two positioning plates 71 facing the both end surfaces of the label roll 1 respectively. When one positioning plate 71 moves toward the center and abuts one end surface of the label roll 1, the other positioning plate 71 also moves toward the center and abuts the other end surface of the label roll 1. When one positioning plate 71 moves away from the label roll 1, the other positioning plate 71 also moves away from the label roll 1. Thereby, the label roll 1 can be easily set at the center.
[0062]
The mount 4 from which the label 5 has been peeled off is wound around a winding shaft 44, and a winding rotating unit 36 that contacts the outer peripheral surface of the roll-shaped mount 4 wound around the winding shaft 44 rotates. Since the roll-shaped backing sheet 4 wound around the take-up shaft section 44 rotates, the winding amount of the backing sheet 4 per unit rotation of the take-up rotating section 36 is constant. Thus, the accuracy of attaching the label 5 can be improved without pulling the mount 4. In addition, since the rotation of the roll-shaped backing sheet 4 is forcibly stopped by the take-up rotating unit 36, the stopping accuracy of the winding of the backing sheet 4 is improved, and the labeling accuracy of the label 5 can be improved. By the way, when the winding shaft 44 is rotated around the axis and the mount 4 is wound, the amount of winding per rotation varies depending on the diameter of the roll-shaped mount 44 wound around the winding shaft 44, and the rotation speed is reduced. It is necessary to control according to the diameter of the roll-shaped backing sheet 44.
[0063]
The winding shaft 44 is movably provided by an inter-axis distance adjusting mechanism 52 that adjusts the inter-axis distance with the winding rotating unit 36 in accordance with the diameter of the roll-shaped backing sheet 4. The center distance between the winding shaft portion 44 and the winding rotating portion 36 is adjusted according to the take-up amount. As a result, the take-up rotating unit 36 always comes into contact with the outer peripheral surface of the roll-shaped backing sheet 4 and can wind up the backing sheet 4. Further, since the winding shaft 44 is moved by the winding unit moving mechanism 53 for moving from the contact position to the non-contact position, the outer peripheral surface of the mount 4 around which the winding rotating unit 36 is wound around the winding shaft 44. , The backing 4 is easily hooked on the winding shaft 44 and the roll-shaped backing 4 wound on the winding shaft 44 is easily taken out. As a result, the time required for setting the label tape 3 and removing the mount 4 can be reduced. In addition, since the driving meshing member 50 having the concave portion 50a facing the gear 51 is moved to mesh with the gear 51 and the driven meshing member 47 is moved, the winding shaft 44 is moved from an arbitrary position. You. Thus, the winding shaft 44 that moves according to the diameter of the roll-shaped backing sheet 4 can be appropriately moved.
[0064]
Further, since the label tape supply mechanism 8 and the label attaching apparatus main body 7 are detachably attached to each other, the label tape supply mechanism 8 can be installed in a place different from the label attaching apparatus main body 7. Further, since the receiving section 72, the sending rotation section 63, and the sending rotation mechanism 70 are unitized, the label tape 3 is sent out to the label applying apparatus main body 7 even from a place remote from the label applying apparatus main body 7. Thereby, as shown in FIG. 9, when there is not enough space above the label attaching apparatus main body 7, a label tape supply driving source (not shown) is installed at a position away from the label applying apparatus main body 7, The label tape supply mechanism 8 is connected to the label tape supply drive source, and the label tape supply mechanism 8 is arranged at a position distant from the label attaching apparatus main body 7.
[0065]
[Second embodiment]
Next, a second embodiment of the label sticking apparatus according to the present invention will be described. FIG. 13 is a side view of the mount recovery mechanism 100, and FIG. 14 is a plan view of the mount recovery mechanism 100. 13 and 14, reference numeral 101 denotes a winding shaft that winds up the mount 102, and reference numeral 103 denotes a winding shaft that contacts the outer peripheral surface of the roll-shaped mount 102 wound around the winding shaft 101 and rotates around the axis. It is a take-off rotating section.
[0066]
As shown in FIGS. 13 and 14, the take-up rotating unit 103 rotates the roll-shaped mount 102 wound around the take-up shaft unit 101, and has a friction coefficient at an intermediate portion of the round bar-shaped shaft member 104. It has a configuration in which a large friction material 105 is coated. In front of the winding rotary unit 103 (on the left side in FIG. 13), a round rod-shaped rotary shaft 106 parallel to the winding rotary unit 103 is arranged. One end (upper side in FIG. 14) of the rotating shaft portion 106 is inserted into a rotating arm plate 107a extending in a direction orthogonal to the axial direction of the rotating shaft portion 106, and the rotating arm plate 107a extends in a vertical direction. It is provided rotatably.
[0067]
FIG. 15 is a partial sectional view showing the AA section shown in FIG. 14, and FIG. 16 is an enlarged plan view of the part shown in FIG. As shown in FIGS. 13, 14, 15, and 16, a pinion 108 that rotates in the vertical direction is inserted into the other (lower side in FIG. 14) end of the rotating shaft 106. Reference numeral 108 denotes a hollow cylindrical portion 108a and a gear portion 108b having a tooth profile formed on the outer periphery. A rotating arm plate 107b opposed to a rotating arm plate 107a provided at one end of the rotating shaft portion 106 is attached to the cylindrical portion 108a. Both ends of the shaft portion 106 of the winding rotating portion 103 are attached to the ends of the two rotating arm plates 107a and 107b, respectively. The winding rotating portion 103 is held between the two rotating arm plates 107a and 107b. I have. The shaft member 104 is provided with a winding unit rotating mechanism such as a motor (not shown) that rotates the winding rotating unit 103.
[0068]
A support arm plate 109 extending in the front-rear direction is fixed to one end surface of the rotating shaft 106 so as to project rearward. At the rear end of the support arm plate 109, a take-up shaft portion 101 arranged in parallel with the take-up rotating portion 103 is cantilevered. The winding shaft 101 is formed in a round bar shape, and a hemispherical concave portion 101a is formed on a tip end surface of the winding shaft 101. In the center of the winding shaft portion 101, a cut 101b extending in the axial direction is formed from the concave portion 101a to the middle of the base end portion.
[0069]
An open / close arm plate 110 facing the support arm plate 109 is disposed outside the rotary arm plate 107b. The opening / closing arm plate 110 includes a sleeve portion 110a fixed to the other end of the rotating shaft portion 106, and an opening / closing portion 110b attached to the sleeve portion 110a via a hinge 111 so as to be openable and closable. A fitting member 112 is fitted to the opening / closing portion 110b so as to fit into the concave portion 101a formed on the distal end surface of the winding shaft portion 101. A pin 113 is attached to the end of the opening / closing portion 110b on the side of the sleeve 110a.
[0070]
Between the sleeve 110a of the opening / closing arm plate 110 and the rotating arm plate 107b, a rack 114 having a tooth profile formed on the upper surface is movably arranged in the front-rear direction. Is formed with a concave portion 114a facing the gear portion 108b of the pinion 108. A hook 114b on which the pin 113 is hooked when the opening / closing section 110b of the opening / closing arm plate 110 is opened is formed on a side surface of the rack 114.
[0071]
The center distance between the winding rotation unit 103 and the winding shaft unit 101 is adjusted by rotating the rotation arm plates 107a and 107b in the vertical direction, and is adjusted according to the diameter of the roll-shaped mount 102. The inter-axis distance adjusting mechanism for adjusting the inter-axis distance with the winding shaft portion 101 includes rotating arm plates 107a and 107b.
[0072]
When the opening / closing portion 110b of the opening / closing arm plate 110 is opened and the pin 113 pushes the hook portion 114b, the rack 114 is moved in the direction of the arrow, and the gear portion 108b of the pinion 108 meshes with the rack 114, and the pinion 108 is Rotated in the direction of the arrow. The pinion 108 is rotated in the direction of the dotted arrow, the rotary arm plate 107b fixed to the cylindrical portion 108a of the pinion 108 is rotated in the vertical direction, and the winding rotary unit 103 is moved away from the roll-shaped backing paper 102. With such a configuration, a winding unit moving mechanism that moves the winding rotation unit 103 from the contact position to the non-contact position is configured.
[0073]
When the opening / closing portion 110b of the opening / closing arm plate 110 is opened and the fitting member 112 fitted in the concave portion 101a formed on the tip end surface of the winding shaft portion 101 is pulled out, the winding with the cut 101b formed therein. The diameter of the shaft portion 101 is reduced by the elastic action of the winding shaft portion 101. Thus, the roll-shaped mount 102 can be easily taken out from the winding shaft 101.
[0074]
As described above, the embodiment of the label sticking apparatus according to the present invention has been described. However, the present invention is not limited to the above-described embodiment, and can be appropriately changed without departing from the gist of the present invention. For example, in the above-described embodiment, the peeling portion 22 is a rectangular plate having an acute angle portion at the tip, but the present invention may have a round tip, a cylindrical member, a roller rotating in the transport direction of the label tape 3, or the like. Good. Further, in the above-described embodiment, the delivery rotating unit 63 is a rotatable roller, but the present invention may be a belt conveyor or the like extending obliquely. Further, in the above-described embodiment, the sending rotary unit 63 is coated with the friction material 65 having a large friction coefficient. The material 65 may be used.
[0075]
In the above-described embodiment, the peeling unit moving mechanism 32 for rotating the driving gear 19 by the drive source 18 such as a motor to move the peeling unit 22 in the front-rear direction is used. A peeling unit moving mechanism 32 that fixes the peeling unit 22 to a reciprocating piston using a cylinder and moves the peeling unit 22 in the front-rear direction may be used. Thereby, the gear and belt of the peeling unit moving mechanism 32 can be omitted. Further, the peeling section 22 may be moved in the front-rear direction using other various actuators. Further, without using the driving source 18, a peeling part moving mechanism 32 for manually rotating the driving gear 19 to move the peeling part 22 in the front-back direction may be used, and also, it is possible to move back and forth along the rail 10. Alternatively, a peeling unit moving mechanism 32 for manually moving the peeling unit 22 provided in the front-rear direction may be used. Thereby, the weight of the label sticking apparatus can be reduced and the cost can be reduced.
[0076]
In the above-described embodiment, the inter-axis distance adjusting mechanism 52 that moves the winding shaft portion 44 to adjust the inter-axis distance between the winding rotating portion 36 and the winding shaft portion 44 is used. According to the present invention, the winding shaft unit 44 may be fixed and the winding rotating unit 36 may be moved, or both the winding rotating unit 36 and the winding shaft unit 44 may be moved. In the above-described embodiment, the winding shaft 44 moves backward, but the present invention may move the winding shaft 44 vertically or diagonally. In the above-described embodiment, the winding shaft portion 44 is urged in the direction of the winding rotating portion 36 by the urging member 49 so that the winding rotating portion 36 and the mount 4 wound in a roll form are brought into contact with each other. However, according to the present invention, the rotatable winding shaft 44 is placed on the two winding rotary units 36 arranged in a line so that the winding rotary unit 36 and the mount 4 wound in a roll form are brought into contact with each other. Is also good.
[0077]
Further, in the above-described embodiment, the drive meshing member 50 and the driven meshing member 47 have a rack shape. However, in the present invention, the drive meshing member 50 may have a gear shape as shown in FIG. As shown in FIG. 11, the driven mesh member 47 may be formed in a gear shape, and as shown in FIG. 12, the drive mesh member 50 and the driven mesh member 47 may be formed in a gear shape.
[0078]
【The invention's effect】
ADVANTAGE OF THE INVENTION According to the label sticking apparatus which concerns on this invention, the mount which contacts the winding rotary part rotates by rotating the winding rotary part which contacts the outer peripheral surface of the roll-shaped mount wound on the winding shaft part. However, since the winding amount of the backing paper per unit rotation of the winding rotating unit is constant, it is possible to secure a stable transfer amount of the label tape and improve the label sticking accuracy.
[Brief description of the drawings]
FIG. 1 is a perspective view of a label tape used in a first embodiment of a label sticking apparatus according to the present invention.
FIG. 2 is a side view illustrating a first embodiment of the label sticking apparatus according to the present invention.
FIG. 3 is a side view illustrating a first embodiment of the label sticking apparatus according to the present invention.
FIG. 4 is a partial detailed view illustrating a peeling section of the first embodiment of the label sticking apparatus according to the present invention.
FIG. 5 is a partial view illustrating a mount collecting mechanism of the first embodiment of the label attaching apparatus according to the present invention.
FIG. 6 is a partial side view illustrating a label tape supply mechanism of the first embodiment of the label sticking apparatus according to the present invention.
FIG. 7 is a partial front view illustrating a label tape supply mechanism of the first embodiment of the label sticking apparatus according to the present invention.
FIG. 8 is a partial view illustrating an inter-axis distance adjusting mechanism of the first embodiment of the label sticking apparatus according to the present invention.
FIG. 9 is a side view illustrating the first embodiment of the label sticking apparatus according to the present invention.
FIG. 10 is a partial view illustrating a take-up section moving mechanism of the first embodiment of the label sticking apparatus according to the present invention.
FIG. 11 is a partial view illustrating a take-up section moving mechanism of the first embodiment of the label sticking apparatus according to the present invention.
FIG. 12 is a partial view illustrating a take-up section moving mechanism of the first embodiment of the label sticking apparatus according to the present invention.
FIG. 13 is a side view illustrating a mount collecting mechanism of a second embodiment of the label sticking apparatus according to the present invention.
FIG. 14 is a plan view illustrating a mount collecting mechanism of a second embodiment of the label sticking apparatus according to the present invention.
FIG. 15 is a cross-sectional view taken along a line AA shown in FIG. 14 for explaining a second embodiment of the label sticking apparatus according to the present invention.
FIG. 16 is a partial plan view illustrating a second embodiment of the label sticking apparatus according to the present invention.
[Explanation of symbols]
4, 102 Backing paper 5 Label 36, 103 Winding rotating unit 43 Winding unit rotating mechanism 44, 101 Winding shaft unit 47 Driven meshing member 50 Drive meshing member 50a recess 51 Gear 52 Inter-axis distance adjusting mechanism 53 Winding unit moving Mechanism 54, 100 Mount collection mechanism

Claims (4)

In a label pasting device provided with a mount collection mechanism having a rotatable winding shaft portion that winds up a strip-shaped mount where the label is peeled off,
The mount collection mechanism includes a winding rotating unit that contacts an outer peripheral surface of the roll-shaped mount wound around the winding shaft, and a winding unit that rotates the winding rotating unit in a winding direction of the mount. A label sticking device, comprising: a part rotating mechanism. The label sticking apparatus according to claim 1,
At least one of the winding shaft portion and the winding rotating portion has an inter-shaft for adjusting the center distance between the winding shaft portion and the winding rotating portion according to the diameter of the roll-shaped backing paper. A label sticking device, further comprising a distance adjusting mechanism. The label sticking apparatus according to claim 1 or 2,
The label attaching characterized in that the mount collecting mechanism is provided with a winding unit moving mechanism that moves at least one of the winding shaft unit and the winding rotating unit from a contact position to a non-contact position. apparatus. The label sticking apparatus according to claim 3,
The winding unit moving mechanism has at least one of a gear that rotates around a fixed shaft and one of the winding shaft unit and the winding rotating unit that is meshed with the gear. A label sticking device, comprising: a driven meshing member; and a drive meshing member meshed with the gear and having a concave portion facing the gear.

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