CN212707057U - A cross cutting location structure for intelligent label - Google Patents

Abstract

The utility model discloses a die cutting positioning structure for intelligent labels, wherein a metal sensor positioned above a die cutting workbench is arranged on die cutting equipment, and a through hole corresponding to the front side of the metal sensor is arranged on the die cutting workbench; the inlay composite tape is provided with a plurality of intelligent label units which are uniformly distributed at intervals, each intelligent label unit is provided with a metal antenna pattern which is connected with the metal sensor in an induction recognition mode, when the metal sensor recognizes the metal antenna pattern, a metal antenna pattern signal is output to the driving device, and after the fixed die cutting time is delayed, the die cutting tool is driven downwards to perform die cutting on the inlay composite tape to obtain a single intelligent label unit; the utility model discloses utilize metal sensor ingeniously can respond to the discernment with intelligent label's metal antenna pattern and be connected for replace among the prior art response location discernment between photoelectric recognition location identification mark and the photoelectric sensor, through simple structure and convenient operation can high-efficiently realize the accurate positioning cross cutting to inlay composite tape.

Description

A cross cutting location structure for intelligent label

Technical Field

The utility model belongs to the intelligent label field of making, concretely relates to cross cutting location structure for intelligent label.

Background

The main working principle of the intelligent tag is that Radio Frequency Identification (RFID) technology is adopted, which is one of automatic Identification technologies, non-contact bidirectional data communication is performed in a Radio Frequency mode, and the intelligent tag is read and written in the Radio Frequency mode, so that the purposes of identifying a target and exchanging data are achieved.

In the production process of the intelligent label, after the intelligent label antenna strip is subjected to inlay compounding by the compounding machine, the intelligent label antenna strip is required to be die-cut into single intelligent label hanging tags by the die cutting machine, and the single intelligent label hanging tags can be packaged and delivered out of a warehouse after various subsequent treatments. In order to ensure accurate die cutting size positioning in the die cutting process of the die cutting machine, a photoelectric identification positioning identification mark capable of being identified by a photoelectric sensor is printed in the printing process before compounding, so that when the die cutting machine performs die cutting processing, the die cutting machine can accurately position the die cutting process through identification communication connection between the photoelectric sensor and the photoelectric identification positioning identification mark, and the die cutting of the intelligent tag hanging plate with the expected size is completed. However, this technique not only requires the pre-printing of the positioning and identification mark, which obviously increases the manufacturing process and the cost of the smart label, but also requires the printing of the positioning and identification mark with accurate position, otherwise the positioning will fail.

The applicant therefore decided to seek technical solutions to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model aims at providing a cross cutting location structure for intelligent label utilizes metal sensor ingeniously can carry out the response discernment with intelligent label's metal antenna pattern and be connected for replace among the prior art response location discernment between photoelectric recognition location identification mark and the photoelectric sensor, can realize the accurate location cross cutting to inlay composite tape through simple structure and convenient operation by high efficiency.

The utility model adopts the technical scheme as follows:

a die cutting positioning structure for an intelligent label comprises a conveyor belt used for conveying an inlay composite tape, wherein the conveyor belt automatically conveys the inlay composite tape to be die-cut to a die cutting workbench of a die cutting device, a die cutting tool is arranged on the die cutting workbench, the die cutting tool is driven by a driving device to selectively die-cut the inlay composite tape below the die cutting tool, a metal sensor positioned above the die cutting workbench is mounted on the die cutting device, and meanwhile, a through hole corresponding to the front side of the metal sensor is formed in the die cutting workbench, so that the signal output by the metal sensor is prevented from being blocked; the inlay composite tape is provided with a plurality of intelligent label units which are uniformly distributed at intervals, each intelligent label unit is provided with a metal antenna pattern which is connected with the metal sensor in an induction recognition mode, when the metal sensor recognizes the metal antenna pattern, a metal antenna pattern signal is output to the driving device, and after the fixed die cutting time is delayed, a die cutting tool is driven downwards to perform die cutting on the inlay composite tape to obtain a single intelligent label unit.

Preferably, the metal sensor is a high-frequency oscillation type metal sensor, and the metal antenna pattern is an aluminum foil strip.

Preferably, the aluminum foil strips comprise a first aluminum foil strip and a second aluminum foil strip which are parallel, a third aluminum foil strip which is vertically distributed is arranged between the first aluminum foil strip and the second aluminum foil strip, and the length direction of the third aluminum foil strip is the same as the conveying direction of the conveying belt; simultaneously first aluminium foil is rectangular is relative with second aluminium foil is rectangular the central line of third aluminium foil is the symmetric distribution, just metal sensor and third aluminium foil are rectangular to be in the collinear, work as metal sensor response discerns when the third aluminium foil is rectangular to be located it under, to drive arrangement outputs metal antenna pattern signal.

Preferably, the distance between the first aluminum foil strip and the second aluminum foil strip in a single smart label unit is 2-4mm, and the distance between the first aluminum foil strip and the second aluminum foil strip and the die-cut edge on one side of the first aluminum foil strip and the die-cut edge on the other side of the first aluminum foil strip is 0.5-1 mm.

Preferably, the transmission speed of the conveyor belt is 10-25 m/min, the distance between the die cutting cutter and the metal sensor is 5-20cm, and the fixed die cutting time is 0.12-1.2 seconds.

Preferably, drive arrangement is including the installation the swing mounting bracket of cross cutting tool, the swing mounting bracket passes through drive shaft drive and connects, but the drive shaft is installed on outside mounting panel relatively rotatably, simultaneously the drive shaft adopts the rotating electrical machines to realize relatively outside mounting panel rotates, realizes the swing mounting bracket is relative the horizontal hunting of drive shaft is used for the realization right the stable displacement of cross cutting tool on upper and lower side.

Preferably, the die cutting table and the transfer mounting bracket of the conveyor belt are respectively mounted on the external mounting plate.

It should be noted that the inlay composite tape related to the present application generally includes a release paper layer on the upper layer, a release paper layer on the bottom layer, and an antenna carrier layer in the middle, and the antenna carrier layer is provided with a metal antenna pattern, which are all known in the art, and the embodiment is not specifically described.

The utility model discloses utilize metal sensor ingeniously can respond to discernment with the metal antenna pattern of intelligent label and be connected, be used for replacing among the prior art photoelectric recognition location identification mark and photoelectric sensor between the response location discernment, specifically through install the metal sensor who is located the cross cutting workstation top on the cross cutting equipment, be equipped with the through-hole that corresponds with the metal sensor is positive on the cross cutting workstation simultaneously, avoid the signal of metal sensor output to receive and block, when the via composite tape that conveys the cross cutting workstation through the conveyer belt reachs the through-hole that is located under the metal sensor, if be in the region of non-metal antenna pattern, the signal of metal sensor output does not receive the hindrance equally, and when the metal antenna pattern region once reachs under the metal sensor, the through-hole is covered, the metal antenna pattern is connected with the metal sensor sensitive response discernment fast, because the metal antenna pattern structure on each intelligent label on the inlay composite tape is all the same, and the interval between the adjacent intelligent label is all the same, consequently, regard as location identification point basis with this response identification point, when practical application simultaneously according to the transmission speed of drive belt, the distance of metal antenna pattern and its cross cutting side cut and the distance between metal sensor and the cross cutting cutter set up suitable fixed cross cutting long, and then make the utility model discloses a simple structure and convenient operation can realize the accurate location cross cutting to the inlay composite tape with high efficiency.

Drawings

FIG. 1 is a schematic view of a die cutting positioning structure according to an embodiment of the present invention;

FIG. 2 is an enlarged view of the structure at A in FIG. 1;

fig. 3 is a side view of the structure of fig. 1.

Detailed Description

The embodiment of the utility model discloses a cross cutting location structure for intelligent label, including the conveyer belt that is used for conveying inlay composite tape, the conveyer belt is to the automatic inlay composite tape of waiting the cross cutting of cross cutting equipment of conveying of cross cutting workstation, be equipped with the cross cutting cutter on the cross cutting workstation, the cross cutting cutter is die-cut to inlay composite tape that is located its below under drive arrangement's drive selectivity, install the metal sensor that is located the cross cutting workstation on the cross cutting equipment, be equipped with the through-hole that corresponds with the metal sensor front on the cross cutting workstation simultaneously, avoid the signal of metal sensor output to receive the hindrance; the inlay composite tape is provided with a plurality of intelligent label units which are uniformly distributed at intervals, each intelligent label unit is provided with a metal antenna pattern which is connected with the metal sensor in an induction recognition mode, when the metal sensor recognizes the metal antenna pattern, a metal antenna pattern signal is output to the driving device, and after the fixed die cutting time is delayed, the die cutting tool is driven downwards to perform die cutting on the inlay composite tape to obtain a single intelligent label unit.

In order to make the technical solutions in the present invention better understood, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, but not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts shall belong to the protection scope of the present invention.

Referring to fig. 1, 2 and 3, a die cutting positioning structure for an intelligent label includes a conveyor belt 2 for conveying an inlay composite tape 1, the conveyor belt 2 automatically conveys the inlay composite tape 1 to be die-cut to a die cutting workbench 31 of a die cutting device 3, the die cutting workbench 31 is provided with a die cutting tool 32, the die cutting tool 32 is driven by a driving device 4 to selectively die-cut the inlay composite tape 1 below the die cutting tool 32, the die cutting device 3 is provided with a metal sensor 5 above the die cutting workbench 31, and the die cutting workbench 31 is provided with a through hole 33 corresponding to the front of the metal sensor 5, so as to prevent a signal output by the metal sensor 5 from being blocked; the inlay composite tape 1 is provided with a plurality of intelligent label units 1a which are uniformly distributed at intervals, each intelligent label unit 1a is provided with a metal antenna pattern 11 which is connected with the metal sensor 5 in an induction recognition mode, when the metal sensor 5 recognizes the metal antenna pattern 11, a metal antenna pattern signal is output to the driving device 4, and after the fixed die-cutting duration is delayed, the die-cutting tool 32 is driven downwards to perform die-cutting on the inlay composite tape 1 to obtain a single intelligent label unit 1 a;

preferably, in the present embodiment, the metal sensor 5 is a high-frequency oscillation type metal sensor (which can be directly obtained from commercial products), and the metal antenna pattern 11 is an aluminum foil strip; further preferably, in the present embodiment, the aluminum foil strips include a first aluminum foil strip 11a and a second aluminum foil strip 11b which are parallel to each other, a third aluminum foil strip 11c which is vertically arranged is provided between the first aluminum foil strip 11a and the second aluminum foil strip 11b, and the longitudinal direction of the third aluminum foil strip 11c is the same as the conveying direction of the conveyor belt 2; meanwhile, the first aluminum foil strip 11a and the second aluminum foil strip 11b are symmetrically distributed relative to the center line of the third aluminum foil strip 11c, the metal sensor 5 and the third aluminum foil strip 11c are in the same straight line, and when the metal sensor 5 senses that the third aluminum foil strip 11c is positioned right below the metal sensor, a metal antenna pattern signal is output to the driving device 4;

preferably, in the present embodiment, the distance between the first aluminum foil strip 11a and the second aluminum foil strip 11b in the single smart label unit 1a is 2-4mm, and the distance between the first aluminum foil strip 11a and the second aluminum foil strip 11b and the die-cut edge on one side thereof is 0.5-1 mm; the transmission speed of the conveyor belt 2 is 10-25 m/min, the distance between the die cutting tool 32 and the metal sensor 5 is 5-20cm, and the fixed die cutting time is 0.12-1.2 seconds;

preferably, in the present embodiment, the driving device 4 includes a swing mounting bracket 41 for mounting the die cutting tool 32, the swing mounting bracket 41 is drivingly connected by a driving shaft 42, the driving shaft 42 is relatively rotatably mounted on the external mounting plate 6, and the driving shaft 42 is rotated relative to the external mounting plate 6 by using a rotating motor (shown in the figure), so as to realize the left-right swing of the swing mounting bracket 41 relative to the driving shaft 42, so as to realize the stable displacement of the die cutting tool 32 in the up-down direction, and the overall driving process is stable and reliable, and has a long service life, and can meet the working requirement of high-frequency driving;

preferably, in the present embodiment, the die-cutting table 31 and the conveyor mounting frame 21 of the conveyor belt 2 are mounted on the external mounting plate 6, respectively.

In the embodiment, the metal sensor 5 is skillfully utilized to perform induction identification connection with the metal antenna pattern 11 of the intelligent tag 1a, so as to replace the induction positioning identification between the photoelectric identification positioning identification mark and the photoelectric sensor in the prior art, specifically, the metal sensor 5 positioned above the die-cutting worktable 31 is installed on the die-cutting equipment, and the through hole 33 corresponding to the front surface of the metal sensor 5 is arranged on the die-cutting worktable 31, so that the signal output by the metal sensor 5 is prevented from being blocked, when the inlay composite tape 1 conveyed to the die-cutting worktable 31 through the conveyor belt 2 reaches the through hole 33 positioned right below the metal sensor 5, if the inlay composite tape is positioned in the area of the nonmetal antenna pattern, the signal output by the metal sensor 5 is also not blocked, and when the area of the metal antenna pattern reaches right below the metal sensor 5, the through hole 32 is covered, the metal antenna patterns 11 and the metal sensors 5 are connected in a sensing identification mode quickly and sensitively, the metal antenna patterns 11 on the intelligent labels 1a on the inlay composite tape 1 are identical in structure, and the distances between the adjacent intelligent labels 1a are identical, so that the sensing identification point is used as a positioning identification point base, and in practical application, proper fixed die cutting duration is set according to the transmission speed of the transmission belt 2, the distance between the metal antenna patterns 11 and the die cutting edges of the metal antenna patterns and the distance between the metal sensors 5 and the die cutting tool 32, and accurate positioning die cutting of the inlay composite tape 2 can be achieved efficiently through a simple structure and convenient operation.

It should be noted that, in the embodiment of the present application, when the embodiment is implemented, the setting of the required delay fixed die-cutting time period may be preliminarily set according to the above related factors, and then the fixed die-cutting time period is finally determined through debugging tests, these settings are all routine technical choices that can be made by those skilled in the art based on the structure proposed in the present application, and the present application also does not specifically relate to the innovative contents of the specific calculation method thereof, so that the present application will not particularly describe this part.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (7)

1. A die cutting positioning structure for an intelligent label comprises a conveyor belt used for conveying an inlay composite tape, wherein the conveyor belt automatically conveys the inlay composite tape to be die-cut to a die cutting workbench of a die cutting device, a die cutting tool is arranged on the die cutting workbench, and the die cutting tool is driven by a driving device to selectively die-cut the inlay composite tape below the die cutting tool; the inlay composite tape is provided with a plurality of intelligent label units which are uniformly distributed at intervals, each intelligent label unit is provided with a metal antenna pattern which is connected with the metal sensor in an induction recognition mode, when the metal sensor recognizes the metal antenna pattern, a metal antenna pattern signal is output to the driving device, and after the fixed die cutting time is delayed, a die cutting tool is driven downwards to perform die cutting on the inlay composite tape to obtain a single intelligent label unit.

2. The die-cutting positioning structure according to claim 1, wherein the metal sensor is a high-frequency oscillation type metal sensor, and the metal antenna pattern is an aluminum foil strip.

3. The die-cutting positioning structure of claim 2, wherein the aluminum foil strips comprise a first aluminum foil strip and a second aluminum foil strip which are parallel, a third aluminum foil strip is vertically arranged between the first aluminum foil strip and the second aluminum foil strip, and the length direction of the third aluminum foil strip is the same as the conveying direction of the conveying belt; simultaneously first aluminium foil is rectangular is relative with second aluminium foil is rectangular the central line of third aluminium foil is the symmetric distribution, just metal sensor and third aluminium foil are rectangular to be in the collinear, work as metal sensor response discerns when the third aluminium foil is rectangular to be located it under, to drive arrangement outputs metal antenna pattern signal.

4. A die cutting positioning structure as claimed in claim 3, wherein the distance between the first aluminum foil strip and the second aluminum foil strip in the single smart label unit is 2-4mm, and the distance between the first aluminum foil strip and the second aluminum foil strip and the die cutting edge on one side thereof is 0.5-1 mm.

5. The die cutting positioning structure according to claim 1, wherein the driving speed of the conveyor belt is 10-25 m/min, the distance between the die cutting tool and the metal sensor is 5-20cm, and the fixed die cutting time period is 0.12-1.2 sec.

6. The die cutting positioning structure of claim 1, wherein the driving device comprises a swing mounting frame for mounting the die cutting tools, the swing mounting frame is connected through a driving shaft in a driving manner, the driving shaft is relatively rotatably mounted on an outer mounting plate, and the driving shaft is rotated relative to the outer mounting plate by using a rotating motor, so that the swing mounting frame can swing left and right relative to the driving shaft, and the die cutting tools can be stably displaced in the up-and-down direction.

7. The die cutting positioning structure of claim 6, wherein the die cutting table and the conveyor mounting frame of the conveyor belt are respectively mounted on the external mounting plate.

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