CN103093268A - Ultrahigh frequency woven label electronic label manufacturing method and ultrahigh frequency woven label electronic label - Google Patents

Abstract

The invention relates to the technical field of electronic labels, in particular to an ultrahigh frequency woven label electronic label manufacturing method which comprises the steps of silkscreening parting agent, silkscreening a first transparent oil layer, silkscreening printing ink, silkscreen antenna, packaging ultrahigh frequency chip, silkscreening a second transparent oil layer, silkscreening adhesive, cutting, thermoprint, tearing off a printing piece and the like. According to the ultrahigh frequency woven label electronic label manufacturing method, woven labels are used as base materials, single embedding body is directly printed on a woven label in a thermoprint mode, compared with an existing ultrahigh frequency woven label electronic label manufacturing method, extra wrapping processes are of no need, and accordingly manufacturing processes are simplified, the woven labels are used for the base materials of an ultrahigh frequency woven label electronic label, the woven labels are strong in tensile resistance, not easy to break, and therefore the tensile resistance of the whole electronic label can be improved, and breaking cannot not happen easily. In addition, the invention further discloses the ultrahigh frequency woven label electronic label.

Description

Ultrahigh frequency is knitted mark electronic tag manufacture method and ultrahigh frequency is knitted the mark electronic tag

Technical field

The present invention relates to the electronic label technology field, relate in particular to that a kind of ultrahigh frequency is knitted mark electronic tag manufacture method and ultrahigh frequency is knitted the mark electronic tag.

Background technology

Radio-frequency (RF) identification is RFID(Radio Frequency IDentification) technology, claim again electronic tag, radio frequency identification, be a kind of communication technology, it can be identified specific objective and read and write related data by radio signals.At present, electronic tag is divided into low-frequency electronic label, high-frequency electronic label and UHF electronic (UHF RFID) label usually.Wherein, ultrahigh frequency electronic tag refers to that the frequency range of radio frequency signal work is at hyper band (UHF), certainly, the hyper band of various countries' definition is different, as: China is 840MHz～845MHz or 920MHz～925MHz, Europe is 865MHz～868MHz, and the U.S. is 902MHz～928MHz, and the 860MHz that stipulates in the ISO/IEC18000-6 international standard～960MHz frequency range has contained the ultra-high frequency band of principal market use in the world.The advantages such as ultrahigh frequency electronic tag is high due to its frequency of operation, read-write distance are more suitable for the Product Information Management in single grade, an important directions that has become radio-frequency (RF) identification research and used.

At present, ultrahigh frequency electronic tag mainly comprises inlay (inlay), base material, and inlay is printed in base material, and wherein, part is bonding consists of by antenna stack, ultrahigh frequency chip etc. for inlay.in order to knit the mark (commecial label that namely weaves, English is woven label, be commonly called as again and be " woven label ", to be widely used in dress and personal adornment, shoes and hats, family is spun, the identification (RFID) tag in the fields such as handicraft) be combined with ultrahigh frequency electronic tag, ultrahigh frequency of the prior art is knitted the mark electronic tag, its manufacture normally is printed on inlay PET(polyethylene terephthalate, polyethylene terephthalate), the PVC(Polyvinylchloride), the PP(polypropylene), the ABS(acrylonitrile-butadiene-styrene copolymer) etc. on the base material of colorless and transparent film, form ultrahigh frequency electronic tag, again with this ultrahigh frequency electronic tag parcel (for example: stitching) in knitting mark.Clearly, it is not inlay directly to be printed on to knit put on that this ultrahigh frequency is knitted the mark electronic tag, but needs the extra operations such as parcel, be that manufacturing process is comparatively loaded down with trivial details, and it is wrapped in the ultrahigh frequency electronic tag of knitting in mark, because base material is membraneous material, so stretching resistance is poor, easily fracture.

Summary of the invention

The object of the invention is to provide for the deficiencies in the prior art a kind of ultrahigh frequency to knit mark electronic tag manufacture method, it is designated as base material to knit, and the direct thermoprint of single inlay is put on knitting, thereby simplified manufacturing technique strengthens the stretching resistance of whole electronic tag.

Another object of the present invention is to provides a kind of ultrahigh frequency to knit the mark electronic tag for the deficiencies in the prior art, and it is designated as base material to knit, and the direct thermoprint of single inlay is put on knitting, thereby simplified manufacturing technique strengthens the stretching resistance of whole electronic tag.

To achieve these goals, the invention provides a kind of ultrahigh frequency and knit mark electronic tag manufacture method, this manufacture method comprises the following steps:

A, silk-screen mould release print one deck mould release on the sheet of undertaking the printing of by silk-screen printing technique, form parting agent layer;

B, the transparent oil reservoir of silk-screen first by the surface printing layer of transparent oil of silk-screen printing technique in described parting agent layer, form the first transparent oil reservoir;

C, ink for screen printing by the surface printing one deck printing ink of silk-screen printing technique at described the first transparent oil reservoir, form ink lay;

D, silk-screen antenna directly are printed on antenna the surface of described ink lay by silk-screen printing technique, form antenna stack, and described antenna stack has antenna terminal;

E, encapsulation ultrahigh frequency chip by the antenna terminal of conductive adhesive in described antenna stack, make described antenna stack be electrically connected to described ultrahigh frequency chip, the formation inlay one side of ultrahigh frequency chip belt salient point;

F, the transparent oil reservoir of silk-screen second, by silk-screen printing technique on described antenna stack exposed surface, surface that described ultrahigh frequency chip is exposed all prints layer of transparent oil, forms the second transparent oil reservoir;

G, silk-screen bonding agent by the surface printing layer of adhesive of silk-screen printing technique at described the second transparent oil reservoir, form adhesive phase;

H, cut, with the inlay after silk-screen the described second transparent oil reservoir and the described adhesive phase of silk-screen, cut, form single inlay;

I, thermoprint are put on by the direct thermoprint of hot stamping process described single inlay knitting, and make described single inlay paste to be fixed in by bonding agent and knit mark;

J, tear away the sheet of undertaking the printing of, tear away the sheet of undertaking the printing of, and make the sheet of undertaking the printing of take away parting agent layer.

Preferably, the described sheet of undertaking the printing of is the PET film.

Preferably, undertake the printing of mould release on sheet of being printed in described steps A is to dry to form described parting agent layer under temperature is the conditions of 65 degree, and the thickness of this parting agent layer is 10～20 microns.

Preferably, the clean oil that is printed on the parting agent layer surface in described step B is to dry to form the described first transparent oil reservoir under temperature is the conditions of 65 degree, and the thickness of this first transparent oil reservoir is 10～20 microns; The printing ink that is printed on the first transparent oil reservoir surface in described step C is to dry to form described ink lay under temperature is the conditions of 65 degree, and the thickness of this ink lay is 15～20 microns.

Preferably, the conducting resinl in described step e is to be that 150 degree, binding time are under the condition of 18 seconds in temperature, the one side of ultrahigh frequency chip belt salient point is adhered to the antenna terminal of described antenna stack; The clean oil that is printed on antenna stack exposed surface and ultrahigh frequency chip exposed surface in described step F is to be to dry under 65 conditions of spending to form the described second transparent oil reservoir in temperature, and the thickness of this second transparent oil reservoir is 15～20 microns; The bonding agent that is printed on the second transparent oil reservoir surface in described step G is to dry to form described adhesive phase under temperature is the conditions of 65 degree, and the thickness of this adhesive phase is 15～20 microns; Bonding agent in described step I is to be 130～160 degree, thermoprint time to be that 6～12 seconds, pressure of hot stamping are under the condition of 3～5 kilograms/square centimeter in temperature, by hot stamping process, the direct thermoprint of described single inlay is put on knitting.

Preferably, the described target specific inductive capacity of knitting is 2.5～20; The length of the antenna stack in described step D is less than or equal to 10 centimetres, and the width of described antenna stack is less than or equal to 7 centimetres.

Preferably, antenna stack in described step D is conductive silver slurry layer, this conductive silver slurry layer is by silk-screen printing technique, conductive silver paste to be printed on described ink lay surface and is to dry under the conditions of 120 degree to form in temperature, and the thickness of described conductive silver slurry layer is that 15～20 microns, conduction sheet resistance are for being not more than 50 ohm.

Correspondingly, the present invention also provides a kind of ultrahigh frequency to knit the mark electronic tag, comprise single inlay, be used for the mark of knitting as base material, the bottom end surface of described single inlay is coated with adhesive phase, described single inlay be by the direct thermoprint of hot stamping process in the described mark of knitting, described single inlay is pasted by described adhesive phase is fixed in the described mark of knitting; Described single inlay also comprises the first transparent oil reservoir, ink lay, antenna stack, ultrahigh frequency chip, the second transparent oil reservoir, described ink lay is covered in the bottom end surface of described the first transparent oil reservoir, described antenna stack is covered in the bottom end surface of described ink lay, described antenna stack has antenna terminal, the one side of described ultrahigh frequency chip belt salient point makes described antenna stack be electrically connected to described ultrahigh frequency chip by the bottom end surface of conductive adhesive in the antenna terminal of described antenna stack; The described second transparent oil reservoir is covered in exposed surface, described antenna stack bottom, bottom end surface and the outer surface of described ultrahigh frequency chip; Described adhesive phase is covered in the bottom end surface of described the second transparent oil reservoir.

Preferably, described ink lay is to be printed on the bottom end surface of described the first transparent oil reservoir by silk-screen printing technique, described antenna stack is to be printed on the bottom end surface of described ink lay by silk-screen printing technique, the described second transparent oil reservoir is to be printed on exposed surface, described antenna stack bottom, bottom end surface and the outer surface of described ultrahigh frequency chip by silk-screen printing technique, and described adhesive phase is to be printed on the bottom end surface of described the second transparent oil reservoir by silk-screen printing technique; The thickness of described the first transparent oil reservoir is 10～20 microns, and the thickness of described ink lay is 15～20 microns, and the thickness of described the second transparent oil reservoir is 15～20 microns, and the thickness of described adhesive phase is 15～20 microns; Described antenna stack is conductive silver slurry layer, and the thickness of this conductive silver slurry layer is 15～20 microns, conducts electricity sheet resistance for being not more than 50 ohm.

Preferably, the described target specific inductive capacity of knitting is 2.5～20; The length of described antenna stack is less than or equal to 10 centimetres, and the width of described antenna stack is less than or equal to 7 centimetres.

Beneficial effect of the present invention is:

Ultrahigh frequency of the present invention is knitted mark electronic tag manufacture method, is designated as base material to knit, and the direct thermoprint of single inlay is put on knitting, and knits mark electronic tag manufacture method with existing ultrahigh frequency and compares, and need not the extra operations such as parcel, thus simplified manufacturing technique; And, ultrahigh frequency of the present invention knit the mark electronic tag be designated as base material to knit, knit the mark stretching resistance strong, be not easy the fracture, so can strengthen the stretching resistance of whole electronic tag, be not easy the fracture.

Description of drawings

Fig. 1 is the process chart that ultrahigh frequency of the present invention is knitted mark electronic tag manufacture method.

Fig. 2 is the structural representation that ultrahigh frequency of the present invention is knitted the mark electronic tag.

Reference numeral:

1---the first transparent oil reservoir, 2---ink lay, 3---antenna stack, 31---antenna terminal, 4---conducting resinl, 5---the ultrahigh frequency chip, 6---the second transparent oil reservoir, 7---adhesive phase, 8---knit mark.

Embodiment

The present invention is further illustrated below in conjunction with accompanying drawing.

Please refer to Fig. 1, knit the process chart of mark electronic tag manufacture method for ultrahigh frequency of the present invention, ultrahigh frequency of the present invention is knitted mark electronic tag manufacture method and is comprised the following steps:

At first, steps A is that (this mould release is specially the silk-screen mould release, Hengsheng, source, Shenzhen Bao Installed Materials Co., Ltd, model: L896 is cold tears the matte release agent), print one deck mould release on the sheet of undertaking the printing of by silk-screen printing technique, form parting agent layer, parting agent layer can make in the step of back and be easy to tear away the sheet of undertaking the printing of.

Then, step B is the transparent oil reservoir 1 of silk-screen first, by the surface printing layer of transparent oil of silk-screen printing technique in parting agent layer, forms the first transparent oil reservoir 1 of transparent oil reservoir 1, the first and can protect antenna stack 3 and ultrahigh frequency (UHF) chip 5.

Then, step C is ink for screen printing, by the surface printing one deck printing ink of silk-screen printing technique at the first transparent oil reservoir 1, forms ink lay 2, and ink lay 2 can further be protected antenna stack 3 and ultrahigh frequency chip 5, and has the effect that strengthens wash water.

Then, step D is silk-screen antenna (for the ultrahigh frequency RFID antenna), by silk-screen printing technique, antenna directly is printed on the surface of ink lay 2, forms antenna stack 3, and antenna stack 3 has antenna terminal 31.

Then, step e is encapsulation ultrahigh frequency chip 5, and ultrahigh frequency chip 5 is adhered to the antenna terminal 31 of antenna stack 3 with the one side of salient point by conducting resinl 4, because conducting resinl 4 not only has viscosity, and can conduct electricity, institute forms inlay so that antenna stack 3 is electrically connected to ultrahigh frequency chip 5.

Then; step F is the transparent oil reservoir 6 of silk-screen second; by silk-screen printing technique on antenna stack 3 exposed surface, surface that ultrahigh frequency chip 5 is exposed all prints layer of transparent oil, forms the second transparent oil reservoir 6, makes the second transparent oil reservoir 6 can protect antenna stack 3 and ultrahigh frequency chip 5.

Then, step G is that (this bonding agent is specially the silk-screen bonding agent, Guangzhou auspicious Strong printing material company limited; Model: SA-2003C glue), by the surface printing layer of adhesive of silk-screen printing technique at the second transparent oil reservoir 6, form adhesive phase 7, so that the hot stamping process by the back can be pasted on base material with inlay.

Then, step H, cuts the inlay after the transparent oil reservoir 6 of silk-screen second and silk-screen adhesive phase 7 for cutting, and forms single inlay (inlay).

Then, step I is thermoprint, and the single inlay after cutting is being knitted on mark 8 by the direct thermoprint of hot stamping process, makes single inlay paste to be fixed in by bonding agent and knits mark 8.

At last, step J tears away for tearing away the sheet of undertaking the printing of the sheet of undertaking the printing of, and make the sheet of undertaking the printing of take away parting agent layer, because parting agent layer is for being adsorbed in the sheet of undertaking the printing of, so, can take away parting agent layer when tearing away the sheet of undertaking the printing of, thereby the ultrahigh frequency of making finished product is knitted mark electronic tag (as shown in Figure 2).

Wherein, the sheet of undertaking the printing of is PET(polyethylene terephthalate, polyethylene terephthalate) film, adopt the PET film can be conducive to print parting agent layer and hot stamping process, certainly, when producing, according to actual needs, the described sheet of undertaking the printing of also can be the film of other material.

Wherein, undertake the printing of mould release on sheet of being printed in steps A is to dry to form parting agent layer under temperature is the conditions of 65 degree, and the thickness of this parting agent layer is 10～20 microns.

Wherein, the clean oil that is printed on the parting agent layer surface in step B is to dry to form the first transparent oil reservoir 1 under temperature is the conditions of 65 degree, and the thickness of this first transparent oil reservoir 1 is 10～20 microns.

Wherein, the printing ink that is printed on the first transparent oil reservoir 1 surface in step C is to dry to form ink lay 2 under temperature is the conditions of 65 degree, and the thickness of this ink lay 2 is 15～20 microns.

Wherein, conducting resinl 4 in step e is to be that 150 degree, binding time are under the condition of 18 seconds in temperature, ultrahigh frequency chip 5 is adhered to the antenna terminal 31 of antenna stack 3 with the one side of salient point, form the upside-down mounting form of ultrahigh frequency chip 5, antenna stack 3 is electrically connected to ultrahigh frequency chip 5, be that ultrahigh frequency chip 5 is electrically connected to antenna terminal 31 by conducting resinl 4

Wherein, the clean oil that is printed on antenna stack 3 exposed surfaces and ultrahigh frequency chip 5 exposed surfaces in step F is to be to dry under 65 conditions of spending to form the second transparent oil reservoir 6 in temperature, and the thickness of this second transparent oil reservoir 6 is 15～20 microns.

Wherein, the bonding agent that is printed on the second transparent oil reservoir 6 surfaces in step G is to dry to form adhesive phase 7 under temperature is the conditions of 65 degree, and the thickness of this adhesive phase 7 is 15～20 microns.

Wherein, the bonding agent in step I is to be 130～160 degree, thermoprint time to be that 6～12 seconds, pressure of hot stamping are that under the condition of 3～5 kilograms/square centimeter, the direct thermoprint of single inlay after cutting by hot stamping process is being knitted on mark 8 in temperature.

Due to choosing of the specific inductive capacity of base material, be very large on the impact of antenna performance.Excessive when the specific inductive capacity of base material, the dielectric loss of antenna will be very large, cause antenna performance very poor, and will be too small when the specific inductive capacity of base material, and antenna performance is worsened.As preferred scheme, the specific inductive capacity that the present invention knits mark 8 is 2.5～20, and the length of antenna stack 3 is less than or equal to 10 centimetres, and the width of antenna stack 3 is less than or equal to 7 centimetres.Like this, as long as guarantee that the actual gain of antenna is enough large, can guarantee the reading performance of antenna.

Wherein, antenna stack 3 in step D is conductive silver slurry layer, this conductive silver slurry layer is by silk-screen printing technique, conductive silver paste to be printed on ink lay 2 surface and is to dry under the conditions of 120 degree to form in temperature, and the thickness of conductive silver slurry layer is that 15～20 microns, conduction sheet resistance are for being not more than 50 ohm.

Please refer to Fig. 2, corresponding to top embodiment of the method, the embodiment of the present invention also provides a kind of and knits by above-mentioned ultrahigh frequency the ultrahigh frequency that mark electronic tag manufacture method produces and knit the mark electronic tag, it comprises single inlay, is used for marking 8 as knitting of base material, the bottom end surface of single inlay is coated with adhesive phase 7, single inlay is to mark 8 by the direct thermoprint of hot stamping process in knitting, and makes single inlay paste to be fixed in by adhesive phase 7 and knits mark 8; Single inlay also comprises the first transparent oil reservoir 1, ink lay 2, antenna stack 3, ultrahigh frequency chip 5, the second transparent oil reservoir 6, ink lay 2 is covered in the bottom end surface of the first transparent oil reservoir 1, antenna stack 3 is covered in the bottom end surface of ink lay 2, antenna stack 3 has antenna terminal 31, ultrahigh frequency chip 5 is adhered to the bottom end surface of the antenna terminal 31 of antenna stack 3 with the one side of salient point by conducting resinl 4, antenna stack 3 is electrically connected to ultrahigh frequency chip 5; The second transparent oil reservoir 6 is covered in exposed surface, antenna stack 3 bottoms, bottom end surface and the outer surface of ultrahigh frequency chip 5; Adhesive phase 7 is covered in the bottom end surface of the second transparent oil reservoir 6.

Wherein, ink lay 2 is to be printed on the bottom end surface of the first transparent oil reservoir 1 by silk-screen printing technique, antenna stack 3 is to be printed on the bottom end surface of ink lay 2 by silk-screen printing technique, the second transparent oil reservoir 6 is to be printed on exposed surface, antenna stack 3 bottoms, bottom end surface and the outer surface of ultrahigh frequency chip 5 by silk-screen printing technique, and adhesive phase 7 is to be printed on the bottom end surface of the second transparent oil reservoir 6 by silk-screen printing technique; The thickness of the first transparent oil reservoir 1 is 10～20 microns, and the thickness of ink lay 2 is 15～20 microns, and the thickness of the second transparent oil reservoir 6 is 15～20 microns, and the thickness of adhesive phase 7 is 15～20 microns; Antenna stack 3 is conductive silver slurry layer, and the thickness of this conductive silver slurry layer is 15～20 microns, conducts electricity sheet resistance for being not more than 50 ohm.

Wherein, knitting mark 8 specific inductive capacity is 2.5～20; The length of antenna stack 3 is less than or equal to 10 centimetres, and the width of antenna stack 3 is less than or equal to 7 centimetres.

In sum, ultrahigh frequency of the present invention is knitted mark electronic tag manufacture method, to knit mark 8 as base material, the direct thermoprint of single inlay is being knitted on mark 8, knit mark electronic tag manufacture method with existing ultrahigh frequency and compare, need not the extra operations such as parcel, thus simplified manufacturing technique; And ultrahigh frequency of the present invention is knitted the mark electronic tag to knit mark 8 as base material, knits mark 8 stretching resistances strong, is not easy fracture, so can strengthen the stretching resistance of whole electronic tag, is not easy fracture.

Should be noted that at last; above embodiment is only in order to illustrate technical scheme of the present invention; but not limiting the scope of the invention; although with reference to preferred embodiment, the present invention has been done to explain; those of ordinary skill in the art is to be understood that; technical scheme of the present invention is modified or is equal to replacement, all belong to protection scope of the present invention.

Claims (10)

1. a ultrahigh frequency is knitted mark electronic tag manufacture method, it is characterized in that, this manufacture method comprises the following steps:

A, silk-screen mould release print one deck mould release on the sheet of undertaking the printing of by silk-screen printing technique, form parting agent layer;

B, the transparent oil reservoir of silk-screen first by the surface printing layer of transparent oil of silk-screen printing technique in described parting agent layer, form the first transparent oil reservoir;

C, ink for screen printing by the surface printing one deck printing ink of silk-screen printing technique at described the first transparent oil reservoir, form ink lay;

D, silk-screen antenna directly are printed on antenna the surface of described ink lay by silk-screen printing technique, form antenna stack, and described antenna stack has antenna terminal;

E, encapsulation ultrahigh frequency chip by the antenna terminal of conductive adhesive in described antenna stack, make described antenna stack be electrically connected to described ultrahigh frequency chip, the formation inlay one side of ultrahigh frequency chip belt salient point;

F, the transparent oil reservoir of silk-screen second, by silk-screen printing technique on described antenna stack exposed surface, surface that described ultrahigh frequency chip is exposed all prints layer of transparent oil, forms the second transparent oil reservoir;

G, silk-screen bonding agent by the surface printing layer of adhesive of silk-screen printing technique at described the second transparent oil reservoir, form adhesive phase;

H, cut, with the inlay after silk-screen the described second transparent oil reservoir and the described adhesive phase of silk-screen, cut, form single inlay;

I, thermoprint are put on by the direct thermoprint of hot stamping process described single inlay knitting, and make described single inlay paste to be fixed in by bonding agent and knit mark;

J, tear away the sheet of undertaking the printing of, tear away the sheet of undertaking the printing of, and make the sheet of undertaking the printing of take away parting agent layer.

2. ultrahigh frequency according to claim 1 is knitted mark electronic tag manufacture method, and it is characterized in that: the described sheet of undertaking the printing of is the PET film.

3. ultrahigh frequency according to claim 1 is knitted mark electronic tag manufacture method, it is characterized in that: undertake the printing of mould release on sheet of being printed in described steps A is to dry to form described parting agent layer under temperature is the conditions of 65 degree, and the thickness of this parting agent layer is 10～20 microns.

4. ultrahigh frequency according to claim 1 is knitted mark electronic tag manufacture method, it is characterized in that: the clean oil that is printed on the parting agent layer surface in described step B is to dry to form the described first transparent oil reservoir under temperature is the conditions of 65 degree, and the thickness of this first transparent oil reservoir is 10～20 microns; The printing ink that is printed on the first transparent oil reservoir surface in described step C is to dry to form described ink lay under temperature is the conditions of 65 degree, and the thickness of this ink lay is 15～20 microns.

5. ultrahigh frequency according to claim 1 is knitted mark electronic tag manufacture method, it is characterized in that: the conducting resinl in described step e is to be that 150 degree, binding time are under the condition of 18 seconds in temperature, the one side of ultrahigh frequency chip belt salient point is adhered to the antenna terminal of described antenna stack; The clean oil that is printed on antenna stack exposed surface and ultrahigh frequency chip exposed surface in described step F is to be to dry under 65 conditions of spending to form the described second transparent oil reservoir in temperature, and the thickness of this second transparent oil reservoir is 15～20 microns; The bonding agent that is printed on the second transparent oil reservoir surface in described step G is to dry to form described adhesive phase under temperature is the conditions of 65 degree, and the thickness of this adhesive phase is 15～20 microns; Bonding agent in described step I is to be 130～160 degree, thermoprint time to be that 6～12 seconds, pressure of hot stamping are under the condition of 3～5 kilograms/square centimeter in temperature, by hot stamping process, the direct thermoprint of described single inlay is put on knitting.

6. ultrahigh frequency according to claim 1 is knitted mark electronic tag manufacture method, and it is characterized in that: the described target specific inductive capacity of knitting is 2.5～20; The length of the antenna stack in described step D is less than or equal to 10 centimetres, and the width of described antenna stack is less than or equal to 7 centimetres.

7. ultrahigh frequency according to claim 1 is knitted mark electronic tag manufacture method, it is characterized in that: the antenna stack in described step D is conductive silver slurry layer, this conductive silver slurry layer is by silk-screen printing technique, conductive silver paste to be printed on described ink lay surface and is to dry under the conditions of 120 degree to form in temperature, and the thickness of described conductive silver slurry layer is that 15～20 microns, conduction sheet resistance are for being not more than 50 ohm.

8. a ultrahigh frequency is knitted the mark electronic tag, it is characterized in that: comprise single inlay, be used for the mark of knitting as base material, the bottom end surface of described single inlay is coated with adhesive phase, described single inlay be by the direct thermoprint of hot stamping process in the described mark of knitting, described single inlay is pasted by described adhesive phase is fixed in the described mark of knitting; Described single inlay also comprises the first transparent oil reservoir, ink lay, antenna stack, ultrahigh frequency chip, the second transparent oil reservoir, described ink lay is covered in the bottom end surface of described the first transparent oil reservoir, described antenna stack is covered in the bottom end surface of described ink lay, described antenna stack has antenna terminal, the one side of described ultrahigh frequency chip belt salient point makes described antenna stack be electrically connected to described ultrahigh frequency chip by the bottom end surface of conductive adhesive in the antenna terminal of described antenna stack; The described second transparent oil reservoir is covered in exposed surface, described antenna stack bottom, bottom end surface and the outer surface of described ultrahigh frequency chip; Described adhesive phase is covered in the bottom end surface of described the second transparent oil reservoir.

9. ultrahigh frequency according to claim 8 is knitted the mark electronic tag, it is characterized in that: described ink lay is to be printed on the bottom end surface of described the first transparent oil reservoir by silk-screen printing technique, described antenna stack is to be printed on the bottom end surface of described ink lay by silk-screen printing technique, the described second transparent oil reservoir is to be printed on exposed surface, described antenna stack bottom, bottom end surface and the outer surface of described ultrahigh frequency chip by silk-screen printing technique, and described adhesive phase is to be printed on the bottom end surface of described the second transparent oil reservoir by silk-screen printing technique; The thickness of described the first transparent oil reservoir is 10～20 microns, and the thickness of described ink lay is 15～20 microns, and the thickness of described the second transparent oil reservoir is 15～20 microns, and the thickness of described adhesive phase is 15～20 microns; Described antenna stack is conductive silver slurry layer, and the thickness of this conductive silver slurry layer is 15～20 microns, conducts electricity sheet resistance for being not more than 50 ohm.

10. according to claim 8 or 9 described ultrahigh frequencies are knitted the mark electronic tag, it is characterized in that: the described target specific inductive capacity of knitting is 2.5～20; The length of described antenna stack is less than or equal to 10 centimetres, and the width of described antenna stack is less than or equal to 7 centimetres.

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