JP5693343B2 - Inlet multi-row stacker - Google Patents

Description

  The present invention relates to an inlet multiple-row stacker that divides each RFID called an inlet from an RFID label original sheet into a plurality of stackers that are stored in a predetermined number.

  In recent years, RFID media that include an IC module and an antenna and can exchange data in a non-contact manner are becoming cheaper and used as labels in addition to IC cards. In the process of manufacturing a sheet in which a large number of such RFIDs, which are called inlets, are temporarily attached using labels, all the non-defective inlets are temporarily stored in a stacker. On the other hand, in order to increase the speed and efficiency of sheet manufacturing, inlets are arranged in a plurality of rows on the sheet, and accordingly, the stacker needs to be prepared in a plurality of rows.

  Conventionally, when manufacturing an RFID label sheet, for example, Patent Document 1 discloses a technique in which a temporarily attached RFID label is made to be a non-defective product by removing defective products. In Patent Document 1, the IC label of the IC roll label (RFID label) is sequentially inspected, the defective IC label determined to be defective according to the communication state is sequentially transferred to a predetermined mount, and then the number of defective IC labels The non-defective IC label is transferred to a predetermined mount, the non-defective IC label is sequentially transferred from the predetermined mount to the defective IC missing area of the IC roll label, and the non-defective IC label is arranged at equal intervals. Is disclosed.

  Since the IC label sheet disclosed in Patent Document 1 is an IC label arranged in a row and is not suitable for mass production, the applicant applied for Japanese Patent Application No. 2010-209750, In this case, stackers for storing replenishing inlets are arranged in a plurality of rows.

JP 2004-287799 A

  By the way, since it is necessary to always secure a predetermined number of inlets accommodated in the stacker, the application of Japanese Patent Application No. 2010-209750 has a configuration in which a sensor is provided for each stacker. When storing by stacking, it is easier to manage by stacking height that does not require count control than number control.

  However, when stackers are arranged in multiple rows, it is necessary to move and adjust between the stackers depending on the size and spacing of the inlets, and the detection position of the sensor that detects the inlet stack height is the same as the inlet flat stack height. It is necessary to adjust according to the setting. In particular, there is a problem that adjusting the position of each sensor for each stacker becomes complicated as the number of stackers increases.

  Accordingly, the present invention has been made in view of the above problems, and it is possible to easily adjust the interval between the stackers in a plurality of rows and the detection of the inlet stacking height according to the size and interval of the accommodated inlet. An object is to provide a row stacker.

  In order to solve the above-mentioned problems, in the invention of claim 1, the inlets separated from the inlet sheet formed on the base are measured by a plurality of rows of receiving portions, and the flat stack height corresponding to the desired number is measured. Inlet multiple-row stackers that are detected and accommodated at each of the stackers, each stacker corresponding to a predetermined number of guide shafts extending in the direction of the rows and being movable on the base in a predetermined number. An engagement member; an inlet accommodating portion for flatly stacking the singulated inlet provided on the base; and the sensor for detecting a flat stacked height of the inlet accommodated in the inlet accommodating portion, A sensor rotation adjustment shaft extending in the direction of the row is penetrated and provided on the base with a sensor block rotated with rotation of the sensor rotation adjustment shaft. Penetration A support member that supports the sensor block so as to be movable with respect to the axial direction, and the interval between the stackers connected on the sensor rotation adjustment shaft is individually adjusted to adjust the rotation of the sensor. The angle of the sensors of all sensor blocks is adjusted at once by rotating the shaft.

  According to the present invention, the predetermined number of engaging members which are movable in the axial direction corresponding to the predetermined number of guide shafts extending in the row direction and the individualized inlets are provided on the base. An inlet accommodating portion to be stacked and a sensor for detecting the height of the inlet stacked in the inlet accommodating portion are provided, and a sensor rotation adjusting shaft extending in the direction of the row is penetrated and rotated together with the rotation. And a support member that supports the sensor block so as to be movable with respect to the axial direction of the sensor rotation adjustment shaft, thereby individually separating the stackers connected on the sensor rotation adjustment shaft. By adjusting the angle of the sensors in all sensor blocks at once by rotating the sensor rotation adjustment shaft, the spacing between stackers in multiple rows can be adjusted according to the size and spacing of the inlets to be accommodated. Adjustment and The flatly adjustment of height detection of Nretto those which can be facilitated.

It is the conceptual diagram which showed the positioning in the inlet sticking apparatus of the inlet multiple row stacker concerning this invention. It is a block diagram of the inlet multiple row stacker according to the present invention. It is explanatory drawing of the individual stacker incorporation in FIG. It is explanatory drawing of the position adjustment of a stacker and a sensor in FIG. It is explanatory drawing of the cross-sectional shape of the other sensor rotation adjustment shaft and bearing which enable position adjustment of each stacker and a sensor.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
In FIG. 1, the conceptual diagram of positioning in the inlet sticking apparatus of the inlet multiple row stacker which concerns on this invention is shown. The inlet multiple row stacker according to the present invention will be shown as an example provided in an inlet sticking device. In FIG. 1 (A), an inlet sticking device 11 has an inlet sheet supplied from an inlet roll 12 in which, for example, five rows of inlets are formed at predetermined intervals on a substrate, and a reading inspection unit is provided on the conveyance path. 13, Inlet cutting section 14 is arranged.

  The inlet cutting unit 14 is provided with two rotation supply units 15 and 16 having a suction holding function, and supplies each inlet to a supply belt 17 provided in the rotation supply unit 16. As shown in FIG. 1B, a defective product stacker 21 is provided at the tip of the supply belt 17 for stocking the defective product inlet 31A by naturally dropping it. Further, as shown in FIG. 1 (B), for example, five rows of stackers are connected in the width direction of the supply belt 17 to accommodate only the good inlets 31 among the individual inlets 31. A stacker unit 18 according to the present invention is provided. The stacker unit 18 will be described with reference to FIGS.

  In addition, a catcher unit 19 is provided that distributes the good inlets 31 on the supply belt 17 to each stacker provided in each row, and each stacker is provided with an inlet pasting mechanism 20. And the position which should be affixed is detected by the detection part 50 with respect to the peeling paper 23 with which the adhesive conveyed from the upstream of each inlet sticking mechanism 20 was apply | coated, and it makes it stick to an applicable position. .

  FIG. 2 shows a configuration diagram of the inlet multi-row stacker according to the present invention. 2A and 2B, the stacker unit 18 has guide shafts 46 to 48 installed between columns 41 (41A, 41B), 42 (42A, 42B), 43 (43A, 43B). In addition, a bearing is provided between the columns 41 (41A, 41B), and the sensor rotation adjusting shaft 44 is installed. A sensor rotation adjustment knob 45 is provided once on the sensor rotation adjustment shaft 44 (the column 41A side). Then, five rows of stackers 49 </ b> A to 49 </ b> E are connected to the sensor rotation adjusting shaft 44 and the guide shafts 46 to 48. The sensor rotation adjusting shaft 44 and the guide shafts 46 to 48 are extended in the direction of the row of the stackers connected in series.

  In each of the stackers 49A to 49E, as shown in FIG. 2B, an inlet accommodating portion 52 is provided once on the bottom plate 51 as a base, and a sensor support member 53 is erected on the other end side. The inlet accommodating portion 52 is formed by two accommodating portion engaging members 54A and 54B being erected and accommodating portion walls 55A and 55B being erected on both sides thereof. An opening 51A is formed in the bottom plate 51 provided with the inlet accommodating portion 52.

  The opening 51 </ b> A is for taking out the inlet stacked in the inlet accommodating portion 52 by the inlet pasting mechanism 20. The housing engaging members 54A and 54B have bearing holes 54A-1, 54A-2, 54B-1, and 54B-2 (bearing holes 54A-1) that pass through the guide shafts 47A, 47B, 48A, and 48B, respectively. , 54A-2 are not shown in the figure).

  On the other hand, the upper end of the sensor support member 53 has a concave shape, and a sensor block 56 including the sensor S is supported here. The sensor S is for detecting the flat height of the inlet 31 that is flatly stacked in the inlet accommodating portion 52. As shown in FIG. 2 (E), circularly-shaped bearing holes 58A and 58B into which the sensor rotation adjusting shaft 44 is fitted are provided on both sides of the concave shape, and sensors corresponding to the bearing holes 58A and 58B are provided. A block bearing hole 57 that penetrates the rotation adjusting shaft 44 is formed through the sensor block 56.

  Here, as shown in FIG. 2C, the sensor rotation adjusting shaft 44 is a flat portion 44A that is non-circular in cross section and lacks a part of the circular cross section. Accordingly, as shown in FIG. 2 (D), the block bearing hole 57 formed in the sensor block 56 has the same cross-sectional shape as the sensor rotation adjusting shaft 44, and the flat surface portion 57A corresponding to the flat surface portion 44A is provided. It is formed. That is, the sensor block 56 is slidable in the axial direction with respect to the sensor rotation adjusting shaft 44, but has the same cross-sectional shape with respect to the rotation of the sensor rotation adjusting shaft 44 and rotates together. Is.

  Each of the guide shafts 46, 47A, 47B, 48A, 48B and the corresponding bearing holes are circular in cross section, but each of the stackers 49A to 49E is a shaft with respect to the guide shafts 46, 47A, 47B, 48A, 48B. The cross-sectional shape is not limited as long as it is slidable in the direction (column direction).

  Next, FIG. 3 shows an explanatory diagram of incorporating the individual stacker in FIG. In FIG. 3, the sensor rotation adjusting shaft 44 extending in the column direction from the support column 41A is arranged between the bearing holes 58A and 58B of the sensor support member 53 in the stacker 49A and in the block shape of the sensor block 56 supported in the concave shape. The guide shaft 46 extending in the column direction from the support post 41 </ b> A is passed through the bearing hole 53 </ b> A of the sensor support member 53.

  Further, guide shafts 47A, 47B, 48A, 48B extending in the column direction from the columns 42A, 43A are used as bearing holes 54A-1, 54A of the accommodating portion engaging members 42A, 43A constituting the inlet accommodating portion 52 in the stacker 49A. The stacker 49A is incorporated by penetrating -2, 54B-1, 54B-2. Similarly, the stackers 49B to 49E are also incorporated.

  FIG. 4 is an explanatory diagram of the position adjustment of the stacker and sensor in FIG. In FIG. 4A, each of the stackers 49A to 49E is individually movable in the axial direction (column direction) with respect to the sensor rotation adjusting shaft 44 and the guide shafts 46 to 48. Even if the formed block bearing hole 57 has the same non-circular cross-sectional shape as the sensor rotation adjustment shaft, the stackers 49A to 49E are connected to the sensor rotation adjustment shaft 44 and the guide shafts 46, 47A, 47B, 48A, 48B. On the other hand, since it is slidable in the axial direction (row direction), the interval between the stackers can be adjusted individually.

  Further, in FIG. 4B, regardless of whether or not the position adjustment of each of the stackers 49A to 49E is performed, the sensor rotation adjustment knob 45 is set to a flat stacking height of the inlet 31 stacked in the inlet accommodating portion 52. When the angle of the sensor S is adjusted by rotating according to the setting, the block bearing hole 57 formed in the sensor block 56 has the same non-circular cross-sectional shape as the sensor rotation adjusting shaft 44. All of the sensor blocks 56 (56A to 56E) of the stackers 49A to 42E are rotated at a time. Accordingly, it is not necessary to adjust the inlet stack height detection for each stacker, which can be facilitated.

  Next, FIG. 5 shows an explanatory view of the cross-sectional shape of another sensor rotation adjusting shaft and bearings that enable position adjustment of each stacker and sensor. FIGS. 5A to 5C show the cross-sectional shape of the sensor rotation adjusting shaft 44, and all show a non-circular cross-sectional shape, but it is an example, and the cross-sectional non-circular shape is shown. Other shapes are not excluded as long as they are shapes.

  That is, the sensor rotation adjusting shaft 44 has a cross-section with a partially cutout portion having a circular cross section in FIG. 5A with the bearing holes 58A and 58B provided at the tip of the sensor support member 53 circumscribed. 44B is formed into a rectangular shape 44 in FIG. 5B and an elliptical shape in FIG. 5C, and correspondingly formed in the sensor block 56 (56A to 56E). The block bearing hole 57 has the same cross-sectional shape. Accordingly, each of the stackers 49A to 49E is movable in the row direction (axial direction), and the sensor rotation adjusting shaft 44 by the sensor rotation adjusting knob 45 with respect to the sensor block 56 (56A to 56E). It is made to rotate with the rotation.

  As described above, the stackers 49A to 49B can be individually adjusted in the axial direction of the guide shafts 46, 47A, 47B, 48A, and 48B and the sensor rotation adjusting shaft 44, and the sensor block including the sensor S is provided. 56 (56A to 56E) can be adjusted with respect to all the stackers 49A to 49E at a time, so that a plurality of rows of stackers corresponding to the size and interval of the inlets to be accommodated can be adjusted. The adjustment of the interval adjustment and the detection of the flat stack height of the inlet 31 can be facilitated.

  The inlet multiple-row stacker of the present invention can be used in the industrial field of RFID manufacturing in which a predetermined number of inlets separated from the RFID label original sheet are accommodated.

DESCRIPTION OF SYMBOLS 11 Inlet sticking apparatus 12 Inlet roll 13 Reading test | inspection part 14 Inlet cutting part 15,16 Rotation supply part 17 Supply belt 18 Stacker part 19 Catcher part 20 Inlet sticking mechanism 21 Defective product stacker 22 Detection part 23 Release paper 31 Inlet 41-43 Support | pillar 44 Sensor rotation adjustment shaft 45 Sensor rotation adjustment knob 46 to 48 Guide shaft 49 Stacker 51 Bottom plate 52 Inlet housing portion 53 Sensor support member 54 Housing portion engaging member 55 Housing portion wall 56 Sensor block 57 Block bearing hole 58 Bearing hole

Claims (1)

An inlet multi-row stacker for storing individual inlets separated from an inlet sheet formed on a substrate by detecting a flat stacking height corresponding to a desired number in a plurality of rows of storage portions with a sensor,
Each stacker
A predetermined number of engaging members provided on the base so as to be movable in the axial direction corresponding to a predetermined number of guide shafts extending in the direction of the row;
An inlet container for flatly stacking the singulated inlets provided on the base;
The sensor is provided with the sensor for detecting the flat height of the inlet accommodated in the inlet accommodating portion, and the sensor rotation adjustment shaft extending in the direction of the row is penetrated, and rotates with the rotation of the sensor rotation adjustment shaft. A moved sensor block;
A support member which is provided on the base and supports the sensor block so that the sensor rotation adjustment shaft is penetrated and movable in the axial direction;
Have
The distance between the stackers connected on the sensor rotation adjustment shaft is individually adjusted, and the angle of all sensors of the sensor block is adjusted at once by rotation of the sensor rotation adjustment shaft. Inlet multi-row stacker.

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