CN101262085B - Molded ferrite sheet, sintered ferrite substrate and Anneta module - Google Patents
Molded ferrite sheet, sintered ferrite substrate and Anneta module Download PDFInfo
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- CN101262085B CN101262085B CN200810096312.1A CN200810096312A CN101262085B CN 101262085 B CN101262085 B CN 101262085B CN 200810096312 A CN200810096312 A CN 200810096312A CN 101262085 B CN101262085 B CN 101262085B
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Landscapes
- Soft Magnetic Materials (AREA)
- Magnetic Ceramics (AREA)
Abstract
The invention provides molded ferrite sheet, sintered ferrite substrate and Anneta module, this thickness is that the feature of the molded ferrite sheet of 30 μm ~ 430 μm is, in the surface roughness at least one surface, center line average roughness is 170nm ~ 800nm, and maximum height is 3 μm ~ 10 μm, the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 10 ~ 80%.
Description
Technical field
The present invention relates to the molded ferrite sheet of the manufacture of the soft-magnetic sintered ferrite substrate for thin plate individual layer, the soft-magnetic sintered ferrite substrate of thin plate individual layer and Anneta module, this Anneta module uses in the contactless IC tag etc. using RFID (radio frequency identification: RadioFrequencyIdentification) technology.
Background technology
In order to obtain sintered ferrite substrate, fire the shaping sheet material of ferrite powder, the shaping sheet material be blended in by ferrite powder in resin.Now, shaping sheet material set each other (set), sintered ferrite substrate anchor at and fire with on pedestal.When peeling off the sintered ferrite substrate of set, sintered ferrite substrate produces damaged, therefore, in order to prevent set, generally adopt with the following method: molded ferrite sheet before the firing, fire with base surface on apply the demoulding such as Zirconium oxide powder, alumina powder powder, and fire, remove demoulding powder after firing.This operation is very loaded down with trivial details, and is difficult to remove demoulding powder completely, therefore when being used in precise electronic parts etc., there is the situation becoming the foreign substance pollution of equipment.
Such as, Japanese Unexamined Patent Publication 2-305416 publication is the technology of " relating to the ferrite core deform ation prevention ferrite sheet material used when firing ferrite forming body ", record in the prior art: " this ferrite shrinks when firing; in order to prevent distortion during this contraction, setter uses alumina powder as coating powder ".Use ferrite core deform ation prevention poor by the method productivity of ferrite sheet material, need to prepare ferrite sheet material itself in addition, can not use from cost consideration.Use the method for coating powder when coating powder cohesion etc., produce extension when firing and touch, or when molded ferrite sheet is thinner, sintered ferrite substrate undulation, the frequency of breaking increases.
In addition, in Japanese Unexamined Patent Publication 2006-174223 publication, flat substrates is laid the solid sheet (Gu sheet) of square ferrite of length of side 2mm, and is adhesively fixed, and then on top other flat substrates, antenna pattern overlapping, obtain antenna-integrated sheet magnetic material.But, flat substrates arranges evenly and efficiently the solid sheet of ferrite very difficult, and impracticable.
In prior art, when the middle Anneta modules used such as using the contactless IC tag of RFID technique works near metal, magnetic flux is transformed to vortex flow in a metal, can not communicate.As its countermeasure, extensive employing planar makes conductive ring coil be formed as helical form, and with the method for this coil laminated soft magnetic sheet material concurrently, in addition, in recent years, the requirement of the miniaturization of electronic equipment such as portable phone, the high-density installation of electronic unit improves day by day.Even if being strongly required to be arranged near metal also can carry out stable communication, and the Anneta module that the thickness of the laminated body of Anneta module is thinner.
As Anneta module, in Japan Patent No. 3728320 publication, disclose the invention be made up of annulus and sheet magnetic material laminated body.In said structure, before equipment is installed, insertion capacitor in parallel, is adjusted to the frequency that 13.56MHz etc. wishes.But when being installed on electronic equipment and work near metal, the situation that the resonance frequency that there is antenna changes, problem is a lot of in practical.In addition, in Japanese Unexamined Patent Publication 2005-340759 publication, disclose the Anneta module that employing is provided with the structure of metal shielding board in advance.The sheet thickness of the magnetic part of laminated iron oxysome sheet material is set as about 0.5mm by this Anneta module, and with PET or PPS covering surfaces, bonded metal barricade on non-communicating face.This structure is difficult to carry out thin plate, can not adapt to the miniaturization of electronic equipment in recent years.
Summary of the invention
In order to be cleaned, the sintered ferrite substrate of thin layer, problem of the present invention is not use the demoulding such as Zirconium oxide powder, alumina powder powder, and the not set each other of acquisition sintered ferrite substrate, sintered ferrite substrate can not anchor at the molded ferrite sheet fired with on pedestal.And problem of the present invention is that acquisition can not due to residual demoulding powder contamination electronic equipment etc., clean sintered ferrite substrate.
The antenna used near metal parts, usual use is provided with sheet magnetic material etc. in advance and have adjusted the antenna of frequency.But when working near metal parts, the resonance frequency of antenna changes.Therefore, must adjust frequency after being installed on electronic equipment.Problem of the present invention obtains a kind of thin Anneta module, and it does not have this loaded down with trivial details operation, even if install magnetic part in advance, adjust frequency, and is arranged on the nearby metal components of certain electronic equipment, also almost do not have frequency change.
In addition, problem of the present invention is in the antenna being used in nearby metal components, eliminates the instability of the antenna performance caused by the space easily formed between magnetic part and metal shielding board.
Above-mentioned technical task can be completed by following the present invention.
The invention provides the molded ferrite sheet that a kind of thickness is 30 μm ~ 430 μm, it is characterized in that, in the surface roughness at least one surface, center line average roughness is 170nm ~ 800nm, and maximum height is 3 μm ~ 10 μm, the area ratio/occupancy ratio of the plane of disruption cut in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 10 ~ 80% (first inventions).
The present invention is the first molded ferrite sheet of the present invention, utilizes blasting treatment to carry out asperities processing (second the present invention) to molded ferrite sheet surface.
The present invention is the first molded ferrite sheet of the present invention, utilizes Surface Machining to become concavo-convex mould or felt wrapped roll (calenderroll) to carry out press molding (the 3rd the present invention) to molded ferrite sheet surface.
The present invention is the first molded ferrite sheet of the present invention, when apply and dry ferrite dispersion paints to obtain shaping sheet material, the plastic film carrying out blasting treatment applies, transfer surface concavo-convex and obtain shaping sheet material (the 4th the present invention).
The present invention is the first molded ferrite sheet of the present invention, when apply and dry ferrite dispersion paints to obtain shaping sheet material, adjustment average grain diameter is the granularity of the ferrite powder of 0.1 ~ 10 μm, is provided with concavo-convex (the 5th the present invention) on surface.
The present invention is the first molded ferrite sheet of the present invention, and wherein, ferrite is Ni-Zn-Cu spinel-like ferrite or Mg-Zn-Cu spinel-like ferrite (the 6th the present invention).
The present invention's to be a kind of thickness be sintered ferrite substrate of 25 μm ~ 360 μm, it is characterized in that, in the surface roughness at least one surface, center line average roughness is 150nm ~ 700nm, and maximum height is 2 μm ~ 9 μm, the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 5 ~ 70% (the 7th the present invention).
The present invention is the 7th sintered ferrite substrate of the present invention, wherein, ferrite is Ni-Zn-Cu spinel-like ferrite, and the real part μ r ' of magnetic susceptibility during 13.56MHz is more than 80, the imaginary part μ r of magnetic susceptibility " be less than 20 (the 8th the present invention).
The present invention is the 7th sintered ferrite substrate of the present invention, wherein, ferrite is Mg-Zn-Cu spinel-like ferrite, and the real part μ r ' of magnetic susceptibility during 13.56MHz is more than 80, the imaginary part μ r of magnetic susceptibility " be less than 100 (the 9th the present invention).
The present invention is the 7th sintered ferrite substrate of the present invention, and the one side of sintered ferrite substrate is provided with conductive layer (the tenth the present invention).
The present invention is the 7th sintered ferrite substrate of the present invention, and at least one side of sintered ferrite substrate is provided with groove (the 11 the present invention).
As the 7th the present invention or the 8th sintered ferrite substrate of the present invention, at least one side of sintered ferrite substrate is pasted with adhesive film, and on sintered ferrite substrate, is provided with crack (the 12 the present invention).
A kind of Anneta module, it is the conductive ring Anneta module for wireless communication medium and wireless communication medium processing unit, the one side of magnetic part is provided with conductive ring antenna, and be provided with antenna magnetic part face opposing face on be provided with conductive layer, wherein, magnetic part is the 7th the present invention or the 8th sintered ferrite substrate of the present invention.(the 13 the present invention).
As the 13 Anneta module of the present invention, the thickness of conductive layer is less than 50 μm, and sheet resistance is 3 Ω/below (the 14 the present invention).
As the 13 Anneta module of the present invention, wherein, magnetic part is the ferrite sintered substrate of Ni-Zn-Cu spinel-like, and coating acrylic compounds or epoxies electrically-conducting paint are to arrange conductive layer (the 15 the present invention).
As the 13 Anneta module of the present invention, wherein, magnetic part is the ferrite sintered substrate of Mg-Zn-Cu spinel-like, and coating acrylic compounds or epoxies electrically-conducting paint are to arrange conductive layer (the 16 the present invention).
As the 13 Anneta module of the present invention, wherein, magnetic part is the ferrite sintered substrate of Mg-Zn-Cu spinel-like, by utilizing silver paste carry out printing lamination and integrally fire on molded ferrite sheet, arranges conductive layer (the 17 the present invention).
As the 13 Anneta module of the present invention, wherein, magnetic part is the ferrite sintered substrate of Ni-Zn-Cu spinel-like, by utilizing silver paste carry out printing lamination and integrally fire on molded ferrite sheet, arranges conductive layer (the 18 the present invention).
Accompanying drawing explanation
The skeleton diagram of the structural section of Fig. 1 Anneta module of the present invention that to be ferrite be in the ferritic situation of Ni-Zn-Cu spinel-like.
Fig. 2 is the surface configuration image of the molded ferrite sheet of embodiment 2.
Fig. 3 is the data being analyzed image and the area ratio/occupancy ratio obtained by the Bearing of the molded ferrite sheet of embodiment 2.The plane of disruption image, the histogram of each height and the figure of its area ratio/occupancy ratio that cut open in the horizontal direction at 50% depth of maximum height is represented in figure.
Fig. 4 is the surface configuration image of the sintered ferrite substrate of embodiment 2.
Fig. 5 is the data being analyzed image and the area ratio/occupancy ratio obtained by the Bearing of the sintered ferrite substrate of embodiment 2.The plane of disruption image, the histogram of each height and the figure of its area ratio/occupancy ratio that cut open in the horizontal direction at 50% depth of maximum height is represented in figure.
Fig. 6 is the surface configuration image of the molded ferrite sheet of comparative example 2.
Fig. 7 is the data being analyzed image and the area ratio/occupancy ratio obtained by the Bearing of the molded ferrite sheet of comparative example 2.The plane of disruption image, the histogram of each height and the figure of its area ratio/occupancy ratio that cut open in the horizontal direction at 50% depth of maximum height is represented in figure.
Fig. 8 is the surface configuration image of the sintered ferrite substrate of comparative example 2.
Fig. 9 is the data being analyzed image and the area ratio/occupancy ratio obtained by the Bearing of the sintered ferrite substrate of comparative example 2.The plane of disruption image, the histogram of each height and the figure of its area ratio/occupancy ratio that cut open in the horizontal direction at 50% depth of maximum height is represented in figure.
Figure 10 is the surface configuration image of the molded ferrite sheet of comparative example 5.
Figure 11 is the data being analyzed image and the area ratio/occupancy ratio obtained by the Bearing of the molded ferrite sheet of comparative example 5.The plane of disruption image, the histogram of each height and the figure of its area ratio/occupancy ratio that cut open in the horizontal direction at 50% depth of maximum height is represented in figure.
Figure 12 is the surface configuration image of the sintered ferrite substrate of comparative example 5.
Figure 13 is the data being analyzed image and the area ratio/occupancy ratio obtained by the Bearing of the sintered ferrite substrate of comparative example 5.The plane of disruption image, the histogram of each height and the figure of its area ratio/occupancy ratio that cut open in the horizontal direction at 50% depth of maximum height is represented in figure.
Figure 14 is the surface configuration image of the molded ferrite sheet of embodiment 11.
Figure 15 is the data being analyzed image and the area ratio/occupancy ratio obtained by the Bearing of the molded ferrite sheet of embodiment 11.The plane of disruption image, the histogram of each height and the figure of its area ratio/occupancy ratio that cut open in the horizontal direction at 50% depth of maximum height is represented in figure.
Figure 16 is the surface configuration image of the sintered ferrite substrate of embodiment 11.
Figure 17 is the data being analyzed image and the area ratio/occupancy ratio obtained by the Bearing of the sintered ferrite substrate of embodiment 11.The plane of disruption image, the histogram of each height and the figure of its area ratio/occupancy ratio that cut open in the horizontal direction at 50% depth of maximum height is represented in figure.
Figure 18 is the surface configuration image of the molded ferrite sheet of comparative example 10.
Figure 19 is the data being analyzed image and the area ratio/occupancy ratio obtained by the Bearing of the molded ferrite sheet of comparative example 10.The plane of disruption image, the histogram of each height and the figure of its area ratio/occupancy ratio that cut open in the horizontal direction at 50% depth of maximum height is represented in figure.
Figure 20 is the surface configuration image of the sintered ferrite substrate of comparative example 10.
Figure 21 is the data being analyzed image and the area ratio/occupancy ratio obtained by the Bearing of the sintered ferrite substrate of comparative example 10.The plane of disruption image, the histogram of each height and the figure of its area ratio/occupancy ratio that cut open in the horizontal direction at 50% depth of maximum height is represented in figure.
Figure 22 is the surface configuration image of the molded ferrite sheet of comparative example 13.
Figure 23 is the data being analyzed image and the area ratio/occupancy ratio obtained by the Bearing of the molded ferrite sheet of comparative example 13.The plane of disruption image, the histogram of each height and the figure of its area ratio/occupancy ratio that cut open in the horizontal direction at 50% depth of maximum height is represented in figure.
Figure 24 is the surface configuration image of the sintered ferrite substrate of comparative example 13.
Figure 25 is the data being analyzed image and the area ratio/occupancy ratio obtained by the Bearing of the sintered ferrite substrate of comparative example 13.The plane of disruption image, the histogram of each height and the figure of its area ratio/occupancy ratio that cut open in the horizontal direction at 50% depth of maximum height is represented in figure.
Symbol description
1: sintered ferrite substrate
2: dielectric film
3: conductive layer
4: Double-sided adhesive tape
5: conducting ring
6: peeling member
Embodiment
First, carry out describing to molded ferrite sheet of the present invention.
The surface roughness of molded ferrite sheet of the present invention is, center line average roughness (Ra) is 170 ~ 800nm, and maximum height (Rmax) is 3 ~ 10 μm.Preferred center line mean roughness is 180 ~ 700nm, and maximum height is 4 ~ 8 μm.In addition, in the present invention, can not only use center line average roughness, the value of maximum height represents, also need control surface concavo-convex there is frequency.In the Bearing of 100 μm that obtain surface roughness square images analyzes, the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height is 10 ~ 80%, is preferably 15 ~ 75%.As long as within the scope of this, even if then do not use demoulding powder, also can not set between molded ferrite sheet, sintered ferrite substrate of the present invention can be fired, reach object of the present invention.
When center line average roughness lower than 170nm or maximum height lower than 3 μm, the sheet material set when firing.In addition, when center line average roughness more than 800nm or maximum height more than 10 μm time, the contact area of shaping sheet material increases, demoulding difficulty.In addition, fire the sintered ferrite substrate that obtains and lose flatness, easily rupture, be easily mixed into space etc. at itself and the border of dielectric film, conductive layer, sintering sectional area also reduces, and magnetic susceptibility declines, and therefore antenna performance is deteriorated.The thickness of sintered ferrite substrate is after firing in the thin plate of less than 200 μm, and problem is especially large.In addition, in 100 μm of square regions, when the area ratio/occupancy ratio of the plane of disruption that 50% depth of maximum height is cut open is in the horizontal direction lower than 10% or more than 80%, the sheet material set when firing, is difficult to be separated overlapping sintered ferrite substrate.
Ferrite powder for molded ferrite sheet of the present invention is Ni-Zn-Cu spinel-like ferrite powder or Mg-Zn-Cu spinel-like ferrite powder.When using Ni-Zn-Cu spinel-like ferrite powder, be Fe
2o
3the composition of be 40 ~ 50Mol%, NiO be 10 ~ 30Mol%, ZnO to be 10 ~ 30Mol%, CuO be 0 ~ 20Mol%.When using Mg-Zn-Cu spinel-like ferrite powder, be Fe
2o
3the composition of be 40 ~ 50Mol%, MgO be 15 ~ 35Mol%, ZnO to be 5 ~ 25Mol%, CuO be 0 ~ 20Mol%.After mixed oxide powder raw material equably, 2 hours can be fired at 750 DEG C ~ 950 DEG C, and pulverize and fire thing and obtain.Preferably accumulation 50% particle volume diameter is the ferrite powder of 0.5 ~ 1.0 μm.
Below, carry out describing to the manufacture method of molded ferrite sheet of the present invention.
The method obtaining molded ferrite sheet of the present invention is not particularly limited, and the surface of molded ferrite sheet of the present invention is carried out to the method for asperities processing, can be used in the sandblasting processing be widely used in metal grinding etc.That is, the solution be dispersed with in aqueous as the glass, aluminium oxide etc. of grinding agent is injected on molded ferrite sheet, washes, thus carried out the molded ferrite sheet of asperities processing.
As the additive method obtaining molded ferrite sheet of the present invention, also there is following method: melting mixing ferrite powder in thermoplastics, press molding is carried out by the felt wrapped roll carrying out Surface Machining (concavo-convex grinding), the mould that carries out Surface Machining, make its sheet material, carry out asperities processing thus.Thermoplastic resin can use polyethylene (PE), polypropylene (PP), polyvinyl butyral resin (PVB) etc.In addition, the resins such as styrene one ethene one butylene class, olefines can be used as thermoplastic elastomer (TPE).Can two or more thermoplastic resin used in combination and/or thermoplastic elastomer (TPE) as required.As composition, the coupling processing of 10 ~ 50 weight portions is carried out in ferrite powder 1000 weight portion, in this coupling processing ferrite powder 1000 weight portion, resin 70 ~ 120 weight portion is carried out 20 ~ 60 minutes mixing by the mixer etc. that pressurizes at 120 ~ 140 DEG C, and the pressurizing mold using surface to carry out concavo-convex processing afterwards forms.From considerations such as pyrolytics when firing, be suitable for using low density polyethylene (LDPE) (LDPE), polyvinyl butyral resin (PVB) etc.Preferred compositing range is relative coupling agent treatment ferrite 1000 weight portion, and thermoplastic resin is 70 ~ 110 weight portions.
As the additive method obtaining molded ferrite sheet of the present invention, there is method ferrite dispersion paints being coated on plastic film.The cooperation composition of ferrite dispersion paints is that relative to Ni-Zn-Cu ferrite powder 1000 weight portion, polyvinyl alcohol resin is 70 ~ 120 weight portions, and the butyl butyl phthalate as plasticizer is 15 ~ 25 weight portions, and solvent is 400 ~ 600 weight portions.Solvent can use gylcol ether, MEK, toluene, methyl alcohol, ethanol, n-butanol etc.When consider the dispersiveness of ferrite powder, mixing operability, drying property etc. time, coating preferably coordinates compositing range to be that, relative to ferrite 1000 weight portion, poly-butyral resin is 80 ~ 110 weight portions, butyl butyl phthalate is 18 ~ 22 weight portions, and solvent is 450 ~ 550 weight portions.
Method for producing paint is not particularly limited, and uses ball mill as well.Being pre-charged with and adding resin and plasticizer after mixed solvent and ferrite, and mix, thus obtain uniform coating.In order to prevent cracking in coated film when applying dry, it is very important for the coating obtained being carried out fully in vacuum tank decompression de-bubble.
The coating method of ferrite dispersion paints is not particularly limited, and can use roll coater, scraper.Consider from the stability of thickness precision, coating, use scraper as well.Utilize scraper to apply the thickness of hope on the plastic film, at 80 ~ 130 DEG C, drying 30 ~ 60 minutes, can obtain molded ferrite sheet.
The painting application plastic film of ferrite dispersion paints is not particularly limited, can uses and sandblasting processing be carried out to various films such as polyethylene (PE), polypropylene (PP), PETG (PET), polyimides and the film obtained.Thermal stability time dry from the processability on film surface, coating is considered, preferred PETG (PET) film.By using the plastic film having carried out blasting treatment, the concavo-convex of plastic film can be needed on molded ferrite sheet, the shaping sheet material of the surface roughness with hope can be obtained.
The another method obtaining molded ferrite sheet of the present invention is the method being adjusted the surface roughness of molded ferrite sheet by the granularity of ferrite powder.Above-mentioned ferrite dispersion paints is being coated in the method for plastic film, being used in accumulation 50% particle volume diameter is mix the ferrite powder that accumulation 50% particle volume diameter is ferrite powder 5 ~ 40 weight portion of 3 ~ 10 μm in ferrite powder 100 weight portion of 0.1 ~ 1.0 μm, thus, even if use the common plastic film not carrying out sandblasting processing, the molded ferrite sheet of surface roughness of the present invention also can be obtained.When considering the surface roughness of sheet material, be that to mix accumulation 50% particle volume diameter in powder 100 weight portion of 0.3 ~ 0.7 μm be powder 10 ~ 40 weight portion of 3 ~ 7 μm in accumulation 50% particle volume diameter be suitable.
In the present invention, fire above-mentioned molded ferrite sheet, obtain sintered ferrite substrate.
Overlapping about 5 ~ 20 molded ferrite sheets of the present invention on the alumina plate that the porosity is 30% of firing of sintered ferrite substrate of the present invention carry out.Under firing condition, being set using the removing resinous principles such as electric furnace is important with the process (process) making ferrite particle grow.The removing of resin carries out 5 ~ 80 hours at 150 DEG C ~ 550 DEG C, and the growth of ferrite particle is carried out under the condition of 850 DEG C ~ 1200 DEG C, 1 ~ 5 hour.
In order to prevent heat distortion, the fracture of sheet material, the removing of resinous principle carries out as well with keeping uniform temperature after heating up from room temperature with about 10 ~ 20 DEG C/h.In addition, keep uniform temperature after preferably heating up with 30 ~ 60 DEG C/h thereafter, sinter fully, Slow cooling after ferrite particle growth.Wherein, the maintenance temperature and time of each process, the sheet number according to carrying out the molded ferrite sheet processed is chosen to be optimal conditions.
Below, carry out describing to sintered ferrite substrate of the present invention.
In the surface roughness of sintered ferrite substrate of the present invention, center line average roughness (Ra) is 150 ~ 700nm, and maximum height (Rmax) is 2 ~ 9 μm.Preferred center line mean roughness (Ra) is 160 ~ 600nm, and maximum height is 3 ~ 8 μm.
In addition, in 100 μm of square regions, the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height is 5 ~ 70%, is preferably 10 ~ 60%, is more preferably 10 ~ 50%.
By firing above-mentioned molded ferrite sheet, center line average roughness (Ra) can be made to be more than 150nm, maximum height (Rmax) is more than 2 μm, when center line average roughness (Ra) more than 700nm or maximum height (Rmax) more than 9 μm time, lose flatness, easy fracture, the interface of itself and dielectric film, conductive layer is easily mixed into space etc., antenna performance deterioration.Further, sintering sectional area declines, and magnetic susceptibility reduces.The thickness of such as sintered ferrite substrate is after firing in the thin plate of less than 200 μm, becomes larger problem.
In addition, by firing above-mentioned molded ferrite sheet, the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is in the scope of 5 ~ 70%.
The sintered density of sintered ferrite substrate of the present invention is 4.6 ~ 5.0g/cm
3.When the sintered density of sintered ferrite substrate is lower than 4.4g/cm
3time, owing to sintering deficiency, easily rupture, and the real part ur ' step-down of magnetic susceptibility.In addition, do not need to carry out sintering until more than 5.0g/cm
3.Be preferably 4.5 ~ 4.9g/cm
3.
Sintered ferrite substrate of the present invention is provided with adhesive film at least one face, can be used on substrate, arranging crack, making laminated body have bendability.Now, when arranging crack, magnetic susceptibility can reduce, but changes according to the different magnetic susceptibility of the state in crack, therefore the preferred groove that systematicness is set on substrate, because easily produce fracture from the part of groove, so give bendability, and the magnetic characteristic after crack is set can be made to stablize.
The groove that sintered ferrite substrate of the present invention is arranged can be, the angle of the front end arranged in the one side of shaping sheet material by embossing roller for machining, steel edge etc. is the groove of the V-type of 25 ~ 45 degree.
The interval of groove is, the lowest point of groove be spaced apart 1 ~ 5mm.When lower than 1mm, when fractureing sintered ferrite substrate along groove, magnetic susceptibility reduces, and processing difficulties.When more than 5mm, the flexibility of sintered ferrite substrate reduces.The more preferred interval of groove is 2 ~ 4mm.
The degree of depth of groove is 0.4 ~ 0.7 with the ratio (degree of depth/sheet thickness of groove) of the thickness of shaping sheet material.When groove depth/sheet thickness ratio lower than 0.4 time, exist not along the situation of groove fracture, rupture uneven, magnetic susceptibility is unstable.When groove depth is more than 0.7, exists and firing the situation along groove fracture in process.The preferable range of groove depth is the ratio of groove depth/sheet thickness is 0.4 ~ 0.6.
In addition, the pattern of groove sheet face described can be any one in equilateral triangle, clathrate or polygonal etc.Importantly, when sintered ferrite substrate disconnects along groove, make the individual sheet of disconnection (Ge sheet) be a uniform sheet as far as possible, even if make curved substrate, magnetic susceptibility does not also change as far as possible.
Because sintered ferrite substrate of the present invention is thinner; easy fracture; crack is made after bonding diaphragm so fit at least one face; known; when using Ni-Zn-Cu spinel-like ferrite powder; the real part μ r ' of magnetic susceptibility when maintaining 13.56MHz is more than 80, the imaginary part μ r of magnetic susceptibility " be less than 20; give suitable pliability to sintered ferrite substrate, the thin layer sintered ferrite substrate of 25 ~ 360 μm as coil antenna module is excellent especially.
When use Ni-Zn-Cu spinel-like ferrite powder sintered ferrite substrate magnetic susceptibility real part μ r ' lower than 80 time, the coil inductance of Anneta module reduces, and communication distance shortens.Imaginary part μ r when magnetic susceptibility " more than 20 time, loss increases, and the Q value of antenna reduces, communication distance shortening.Preferred μ r " be less than 10.Preferred μ r further " be less than 5.
In addition known, when using Mg-Zn-Cu spinel-like ferrite powder, the real part μ r ' of magnetic susceptibility when maintaining 13.56MHz is more than 80, the imaginary part μ r of magnetic susceptibility " be less than 100; give suitable pliability to sintered ferrite substrate, the thin layer sintered ferrite substrate of 25 ~ 360 μm as coil antenna module is excellent especially.
When use Mg-Zn-Cu spinel-like ferrite powder sintered ferrite substrate magnetic susceptibility real part μ r ' lower than 80 time, the coil inductance of Anneta module reduces, and communication distance shortens.Imaginary part ur when magnetic susceptibility " more than 150 time, loss increases, and the Q value of antenna reduces, communication distance shortening.The real part μ r ' of preferred magnetic susceptibility is more than 85, imaginary part ur " be less than 90.
Below, carry out describing to Anneta module of the present invention.
Anneta module of the present invention, by arranging conductive ring antenna in the one side of the sintered ferrite substrate as magnetic part, and be provided with antenna magnetic part face opposing face on conductive layer be set and obtain.Conductive ring antenna, makes by forming the conducting ring (loop) of Vorticose thickness 20 ~ 30 μm in the one side of the dielectric film such as polyimide film, PET film of thickness 20 ~ 60 μm.
Coating electrically conductive coating in the one side that can be used in the ferrite sintered substrate of thickness 25 ~ 360 μm is also integrally fired after carrying out drying and arranging conductive layer or print lamination silver paste before molded ferrite sheet is fired and arranges the sintered ferrite substrate of conductive layer.The thickness of conductive layer is preferably 5 ~ 50 μm.By two-sided tape bonding conductive ring antenna and the face contrary with the conductor planes of sintered ferrite substrate of thickness 20 ~ 60 μm, conductor planes also pastes same jointing tape, as shown in Figure 1, obtain the Anneta module that gross thickness is 110 ~ 620 μm.
Dielectric film is not particularly limited, as long as sheet resistance is 5M Ω/more than, in order to prevent small leakage current, and preferred 10M Ω/more than.
Can use as the copper of conductive filler and the electrically-conducting paint of powder dispersion in the organic solvent such as butyl acetate, toluene and acrylic resin, epoxy resin of silver.
Coating electrically conductive coating in the one side of sintered ferrite substrate, in the air atmosphere of room temperature to 100 DEG C, dry solidification 30 minutes ~ 3 hours, arranges the conductive layer of 20 ~ 50 μm as well.The sheet resistance of conductive layer is preferably set to 3 Ω/below.The characteristic variations of antenna when working near metal to reduce further, makes sheet resistance be 1 Ω/below.In addition, in order to make laminated thickness thinning, preferably 20 ~ 30 μm.
In addition, the sintered ferrite substrate of band conductive layer also can be processed conducting resinl by raw cook (greensheet) method, is obtained by one firing process.In order to make conductive layer not expose from electronic equipment internal, also can laminated insulation diaphragm.Method as is well known, resonance frequency is also adjusted to 13.56MHz by insertion capacitor in parallel in ring, makes the Anneta module obtained with the frequency resonance of hope.
Conductive ring antenna, adhesive linkage, ferrite sintered substrate, conductive layer is made to touch and carry out integration as described above, and parallel importing capacitor in cyclic loop, resonance frequency is adjusted to the Anneta module of 13.56MHz, even if in the nearby metal components work of various electronic equipment, the change of antenna performance is also few, can guarantee stable communication.
According to the present invention, even if do not use Zirconium oxide powder, alumina powder etc. to carry out demoulding process, also that can obtain not having set, clean, thinner sintered ferrite substrate, can to provide when installing in the electronic device and also can not cause the sintered ferrite substrate of pollution by dispersing etc. of separating powder.
According to the present invention, the real part μ r ' of magnetic susceptibility during by making the 13.56MHz of the sintered ferrite substrate of 25 ~ 360 μm is more than 80, the imaginary part μ r of magnetic susceptibility " be less than 20 (ferrite is the ferritic situation of Ni-Zn-Cu spinel-like) or less than 100 (ferrite is the ferritic situation of Mg-Zn-Cu spinel-like), the magnetic part being applicable to Anneta module can be obtained.It is very large to the thin layer contribution of Anneta module.
According to the present invention, in the Anneta module that nearby metal components uses, forming thin conductive layer as on the sintered ferrite substrate of magnetic part by application, printing lamination, therefore, the thickness of Anneta module can be thinned to about 100 ~ 580 μm.In addition, according to the present invention, adjustment resonance under the state of one lamination conductive ring coil, magnetic part (soft ferromagnetic layer) and conductive layer, the characteristic variations of the antenna therefore after equipment installation is few, thus does not need loaded down with trivial details adjustment after equipment is installed.
According to the present invention, in the Anneta module that nearby metal components uses, because all there is not space between magnetic part and conductive layer, so antenna performance is highly stable.
According to the present invention, on the sintered ferrite substrate being used as magnetic part, be fitted with adhesive film at least one face, the crack of the bendability producing substrate is set, thus magnetic part can be made to have pliability, therefore processing ease, and the characteristic variations of the Anneta module caused by the crack of magnetic part can be made minimum.
Molded ferrite sheet of the present invention easily can arrange suitable surface roughness at least one face, even if fire under the state of overlap, sintering when not using demoulding powder, also industrially can obtain the molded ferrite sheet of not set.
Sintered ferrite substrate of the present invention, even if thinner thickness also can realize high magnetic susceptibility, and do not use the demoulding such as zirconia, aluminium oxide powder ground overlapping and fire and manufacture, therefore, there is no powder contamination when installing in the electronic device, being suitable for the purposes of the antenna module-use magnetic core of the high-density installation in RFID (RadioFrequencyIdentification: radio-frequency (RF) identification) universal fast in recent years.
The one side of sintered ferrite substrate of the present invention is touched, lamination has the conductive layer of 20 ~ 50 μm, and the Anneta module making itself and conductive ring antenna integrated, even if work in the electronic equipment in RFID (RadioFrequencyIdentification) communication near metal, its characteristic also has almost no change, and, because the thinner thickness of module can be made, so the high-density installation of electronic equipment can also be tackled.
Embodiment
Describe the assay method of each measured value shown in embodiment.
[surface roughness]
Use atomic force microscope (DigitalInstrument society manufactures NanoScopeIII), measure 100 μm of square regions, ask for the surface roughness (center line average roughness Ra, maximum height Rmax) of molded ferrite sheet and sintered ferrite substrate.
In order to the concaveconvex shape of presentation surface, quantized by the Bearing analysis software of same device.According to the image of the surface roughness asked for, obtain the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of its maximum height (Rmax), thus concaveconvex shape state can be compared.That is, when molded ferrite sheet, if this area ratio/occupancy ratio is 10 ~ 80%, then the set after firing can be prevented.When measuring the sintered ferrite substrate after firing, the area ratio/occupancy ratio when sintered ferrite substrate of set is not had to be 5 ~ 70%.The mensuration of the surface roughness of the sintered ferrite substrate that the set of comparative example is serious, does not have the position of set to carry out in the substrate of fracture.
[accumulating 50% particle volume diameter]
Use Nikkiso Company Limited MicrotracMT3300, utilize damp process to measure the average grain diameter of ferrite powder.In the aqueous solution 100ml comprising the hexa metaphosphoric acid as dispersant (acid of ヘ キ タ メ タ リ Application) of 0.2% and the non-ionic surfactant as interfacial agent (manufacture of TritonX-100DowChemical society) of 0.05%, add ferrite powder 5g, by ultrasonic homogenizer (model: 300W, Nikkiso Company Limited manufacture) carry out the dispersion of 300 seconds after, measure volume distributed median in minute 30 seconds, measurement range 0.021 ~ 1408 μm, solvent refractive index 1.33, particle refractive index 2.94, shape of particle under being aspheric condition.
[thickness of sheet material]
To cutting into 4 angles that overall dimension is the shaping sheet material of the quadrangle of length of side 80mm, the electronic digital display indicating device ID-S112 using Mitutoyo Co., Ltd. to manufacture measures the thickness of sheet material, averaged.
[sintered density]
The sintered density of sintered ferrite substrate is calculated by the volume and weight obtained according to the outside dimension of sample.
[magnetic susceptibility]
The mensuration of magnetic susceptibility, cuts into ring (ring) shape of external diameter φ 14mm, internal diameter φ 8mm by sintered ferrite substrate, measure the thickness of ring, make test film.Use impedance analyzer HP4291A (manufacture of Hewlett-Packard society) and be installed on the fixture (HP1645A) of its testboard, or impedance analyzer E4991A (manufacture of AgilentTechnologies society) and be installed on the fixture (16454A) of its testboard, measure value during frequency 13.56MHz.
[resonance frequency and resonance degree]
The resonance characteristics of Anneta module is, measures by the resonance characteristics of the conductive ring antenna of the Structure composing recorded in Fig. 1.Its method is, measure the frequency characteristic of the impedance of the supply line of the laminated antenna module shown in Fig. 1, capacitor is connected in parallel in supply line, and adjust its electrostatic capacitance, under the state that resonance frequency is 13.56MHz, the impedance analyzer HP4291A using Hewlett-Packard society to manufacture measures resonance degree Q.In embodiment 7 ~ 9,16 ~ 18 and comparative example 6 ~ 8,14 ~ 16, in order to compare, resonance frequency when lamination has Anneta module and an iron plate and the mensuration of resonance degree Q, carry out under the condition set when non-lamination iron plate.
[sheet resistance]
Use low-resistivity meter Loresta-GP (MCP-T600 type, Mitsubishi chemical Co., Ltd manufactures), measured the sheet resistance of conductive layer by 4 sonde methods (according to JISK7149).
[embodiment 1]
By 1000 weight portions be adjusted to accumulation 50% particle volume diameter be 0.7 μm Ni-Zn-Cu ferrite powder (composition: Fe
2o
3: 48.5Mol%, NiO:20.5Mol%, ZnO:20.5Mol%, CuO:10.5Mol%, firing condition: 850 DEG C 90 minutes) carry out by the titante coupling agent (Ajincomoto Co., Inc manufacture KR-TTS) of 10 weight portions ferrite powder 1000 weight portion that surface treatment obtains, with thermoplastic elastomer (TPE) (, TOSOH Co., Ltd. manufacture LUMITAC22-1) 50 weight portions, density 0.9g/cm
3polyethylene 100 weight portion, stearic acid 20 weight portion, by pressurization mixer at 130 DEG C mixing 40 minutes.Sandblasting is used to be processed as the iron plate of center line average roughness 450nm, maximum height 8 μm, at temperature 160 DEG C, pressure 100kg/cm
2, 3 minutes pressing times condition under, mixing thing is formed to the ferrite resin obtained and carries out press molding, make that thickness is 77 μm, size is the molded ferrite sheet of the quadrangle of length of side 100mm.By overlapping 10 of this sheet material.Clamped up and down as on the aluminium oxide setter (Kikumizu Chemical Industry Co., Ltd.'s manufacture) firing pedestal, degreasing 10 hours at 500 DEG C, at 920 DEG C, fire 2 hours, peel off sinter after cooling, plate can not have easily to be stripped damagedly.The quadrangle that the sintered ferrite substrate thickness obtained is 65 μm, overall dimension is length of side 80mm.The test film of external diameter φ 14mm, internal diameter φ 8mm is cut out from this sintered plate, use impedance analyzer HP4291A (manufacture of Hewlett-Packard society) and be installed on the fixture (HP16454A) of its testboard, magnetic susceptibility when obtaining frequency 13.56MHz is μ r ' is 98, μ r " be 2.2, there is no set and the sintered ferrite substrate had excellent magnetic characteristics.
The surface roughness of the molded ferrite sheet obtained is, center line average roughness is 420nm, maximum height is 6.5 μm, and in 100 μm of square regions, the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height is 48%.In addition, the surface roughness of sintered ferrite substrate is, center line average roughness is 400nm, and maximum height is 5.5 μm, in 100 μm of square regions, the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height is 45%.
[embodiment 2]
Using Ni-Zn-Cu ferrite 100 weight portion identical with embodiment 1 and BPBG (butylphthalylbutylglycolate) 2 weight portion, polyvinyl alcohol resin (Sekisui Chemical Co., Ltd manufactures S-LECBBM-1) 12 weight portions, be mixed into n-butanol 4 as solvent: solvent 60 weight portion of toluene 6; with ball mill mixing, dissolving, dispersion, obtain ferrite dispersion paints.After decompression de-bubble being carried out to ferrite dispersion paints by oily rotary vacuum pump, in one side, with scraper being become by blasting treatment that center line average roughness is 530nm, maximum height is that the PET film (Panac Industrial Co., Ltd manufactures Le ミ マ Star ト 50S200 ト レ ス) of 5.6 μm carries out certain thickness coating, by the heated-air drying 30 minutes of 100 DEG C, obtain the molded ferrite sheet of thickness 204 μm.The molded ferrite sheet obtained is cut into the size of the quadrangle of length of side 100mm, peel off from PET film, under the same conditions as example 1 the sheet material obtained is fired.Carry out the evaluating characteristics of the sintered ferrite substrate obtained, result, thickness is 160 μm, and overall dimension is the quadrangle of length of side 80mm, magnetic susceptibility during 13.56MHz is μ r ' is 96, μ r " be 3, there is no set, easily peel off.
The surface roughness of the molded ferrite sheet obtained is, center line average roughness is 370nm, maximum height is 4.0 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 73%.The center line average roughness in the contrary face in the face contacted with PET film, maximum height be respectively 104nm, 1.3 μm, the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 93%, known can passing through uses PET film, wittingly control surface roughness.In addition, the surface roughness of sintered ferrite substrate is, center line average roughness is 292nm, and maximum height is 3.5 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 12%.
[embodiment 3]
Mixing accumulation 50% particle volume diameter is the Ni-Zn-Cu ferrite powder (composition: Fe of 6 μm
2o
3: 48.5Mol%, NiO:20.5Mol%, ZnO:20.5Mol%, CuO:10.5Mol%, firing condition: 1000 DEG C 90 minutes) 300 weight portions and accumulation 50% particle volume diameter identical with embodiment 1 be Ni-Zn-Cu ferrite 700 weight portion of 0.7 μm, in addition obtain ferrite resin by method similarly to Example 1 and form mixing thing.Use and be processed as the iron plate that center line average roughness is 120nm, maximal roughness is 2 μm, at temperature 160 DEG C, pressure 100kg/cm
2, 3 minutes pressing times condition under press molding is carried out to the mixing thing obtained, make thickness 200 μm, overall dimension 100mm molded ferrite sheet.Process the evaluation of the sintered ferrite substrate of the sheet material gained obtained under the same conditions as example 1, result, thickness is 167 μm, magnetic susceptibility during 13.56MHz is μ r ' is 80, μ r " be 1.1, there is no set, easily peel off.
Owing to being mixed with ferrite oversize grain, the surface roughness of the molded ferrite sheet obtained is, center line average roughness is 270nm, maximum height is 5.0 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 20%.In addition, the surface roughness of sintered ferrite substrate is, center line average roughness is 250nm, and maximum height is 4.0 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 18%.
[embodiment 4]
Except obtain condition that thickness is the molded ferrite sheet of 42 μm when applying with scraper except, obtain sintered ferrite substrate by method similarly to Example 2.Carry out the evaluating characteristics of the sintered ferrite substrate obtained, result, thickness is 37 μm, magnetic susceptibility during 13.56MHz is μ r ' is 95, μ r " be 2, there is no set, easily peel off.
The surface roughness of the molded ferrite sheet obtained is, center line average roughness is 435nm, maximum height is 6.3 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 52%.In addition, the surface roughness of sintered ferrite substrate is, center line average roughness is 425nm, and maximum height is 4.9 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 50%.
[embodiment 5]
Except obtain condition that thickness is the molded ferrite sheet of 405 μm when applying with scraper except, obtain sintered ferrite substrate by method similarly to Example 2.Carry out the evaluating characteristics of the sintered ferrite substrate obtained, result, thickness is 350 μm, magnetic susceptibility during 13.56MHz is μ r ' is 102, μ r " be 3.2, there is no set, easily peel off.
The surface roughness of the molded ferrite sheet obtained is, center line average roughness is 409nm, maximum height is 6.8 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 58%.In addition, the surface roughness of sintered ferrite substrate is, center line average roughness is 388nm, and maximum height is 5.6 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 41%.
[comparative example 1]
Make ferrite resin by method similarly to Example 1 and form mixing thing, use and be processed into the iron plate clamping constituent that center line average roughness is 120nm, maximal roughness is 2 μm, form, in addition make sintered ferrite substrate under identical condition, result, set is serious, be difficult to peel off, although a part is stripped out, palette ruptures, and fails the sintered ferrite substrate of the quadrangle producing one piece of length of side 80mm.And the magnetic susceptibility during 13.56MHz of sintered ferrite substrate is μ r ' is 98, μ r " be 1.9.
The surface roughness of the molded ferrite sheet obtained is, center line average roughness is 115nm, maximum height is 1.8 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 2%.In addition, the surface roughness of sintered ferrite substrate is, center line average roughness is 98nm, and maximum height is 1.1 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 2%.
[comparative example 2]
Ferrite dispersion paints is made by method similarly to Example 2.The center line average roughness not carrying out sandblasting processing be 17nm, maximum height is 0.3 μm, thickness is in the PET film of 50 μm, with scraper, certain thickness coating is carried out to the coating obtained, by 100 DEG C of heated-air dryings 30 minutes, obtain the molded ferrite sheet of thickness 202 μm.This sheet material to be peeled off from PET film, and overlapping 10, carry out identical with embodiment 1 firing process, carry out the evaluation of the sintered ferrite substrate obtained.Thickness is 165 μm, and set is serious, can not peel off.
The surface roughness of the molded ferrite sheet obtained is, center line average roughness is 66nm, maximum height is 1.3 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 90%.In addition, the surface roughness of sintered ferrite substrate is, center line average roughness is 44nm, and maximum height is 0.9 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 1%.
[comparative example 3]
After making sheet material by the method same with comparative example 2, from PET film releasing sheet, on the molded ferrite sheet face contacted with the face of film, the Zirconium oxide powder (N. E. Chemcat Corp.'s manufacture) that 50mg average grain diameter is 5 μm is applied by brushing (brushing), carry out afterwards same with comparative example 2 firing process, carry out the evaluation of the sintered ferrite substrate obtained.The magnetic susceptibility during 13.56MHz of sintered ferrite substrate is μ r ' is 96, ur " be 1.8, but confirm to there is the position that Zirconium oxide powder anchors at sintered ferrite substrate surface, when it is removed with brush, 3 pieces of plates fractures in 10 pieces.Coating and the removing operation of powder are very loaded down with trivial details, can not remove Zirconium oxide powder completely.
[comparative example 4]
Use sandblasting to be processed into the iron plate that center line average roughness is 1200nm, maximum height is 14 μm, in addition obtain sintered ferrite substrate by method similarly to Example 1.There is no set, peel off while plate can not be damaged.The magnetic susceptibility during 13.56MHz of sintered ferrite substrate is μ r ' is 75, μ r " be 0.6, be the value that can not meet magnetic characteristic.This is because surface roughness is excessive, result increases in space on the cross section of sintered ferrite substrate, and therefore magnetic susceptibility reduces.
[comparative example 5]
Ferrite dispersion paints is made by method similarly to Example 2.Carrying out roughness processing, center line average roughness is 252nm, maximum height is in the PET film (TeijinDuPontFilms Co., Ltd. manufactures U4-50) of 3.3 μm, with scraper, certain thickness coating is carried out to the coating obtained, in 100 DEG C of hot blasts, drying 30 minutes, obtains the molded ferrite sheet of thickness 200 μm.This sheet material is peeled off and overlapping 10 from PET film, carries out identical with embodiment 1 firing process, carry out the evaluation of the sintered ferrite substrate obtained.Thickness is 171 μm, and set is serious, can not peel off.The surface roughness of the molded ferrite sheet obtained is, center line average roughness is 319nm, maximum height is 3.3 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 95%.In addition, the surface roughness of sintered ferrite substrate is, center line average roughness is 246nm, and maximum height is 3.3 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 96%.
That is, from this result, in order to pursue effect of the present invention, be not only surface roughness, the control of the area ratio/occupancy ratio of the plane of disruption is also very important.
Result table of induction is shown in table 1.
[table 1]
[embodiment 6]
The concavo-convex machined surface of the sintered ferrite substrate obtained by embodiment 1 is pasted the two-sided tape (goods name 467MP, Sumitomo 3M manufacture) of thickness 50 μm, makes the laminated body be made up of 63 μm of sintered ferrite substrate layers and 50 μm of adhesive linkages.In order to make this laminated body, there is bendability, be loaded in thickness 10mm, expansion ratio is about on the polyurethane sheet of 10 times, use the rubber rollers that profile is about 50mm, width is about 15cm, the pressure being about 1kg/cm with roller linear pressure is to laminated body longitudinal and transverse pressurization respectively, in sintered ferrite substrate entirety, crack is set, stamping-out becomes profile 14mm φ, internal diameter 8mm φ afterwards, and measures magnetic susceptibility.Magnetic susceptibility when 13.56MHz is that μ r ' is 83, μ r " be 0.8.In addition, after same laminated body being wound into the iron staff of profile 30mm φ, cut out test film similar to the above, measure magnetic susceptibility, consequently μ r ' be 82.5, μ r " be 0.8, have almost no change; bendability is good, and magnetic susceptibility μ r ' is more than 80, also well.
[embodiment 7]
The PET film being produced on 25 μm is provided with the flat plane antenna of 7 circles (turn) Vorticose conducting ring, the shape of its annular is the rectangle of vertical 45mm, horizontal 75mm.In addition, use the Ni-Zn-Cu ferrite used in embodiment 1, made the molded ferrite sheet of thickness 180 μm by method similarly to Example 2, utilize Thomson cutter (the ト system ソ Application of each 30 ° of the point of a knife of V-type at shaping sheet material on the surface
), the V groove of the degree of depth about 90 μm is set with the clathrate being spaced apart 2mm.The molded ferrite sheet of the trough of belt obtained is cut into the quadrangle of length of side 100mm, peel off from PET film, under the same conditions as example 1 the sheet material obtained is fired.The sintered ferrite substrate thickness obtained is 150 μm, and overall dimension is the quadrangle of length of side 80mm.Do not have on the face of groove at sintered ferrite substrate, be coated in polyester resin the electrically-conducting paint (trade name DotiteXE-9000, Fujikura Kasei Co., Ltd manufacture) being dispersed with silver and copper powders, at 50 DEG C, drying 30 minutes, arranges the conductive layer of 30 μm.The sheet resistance of conductive layer is 0.2 Ω/.On this conducting surface after sticking two-faced adhesive tape band (goods name 467MP, Sumitomo 3M Co., Ltd. manufactures), cut ferrite sintered substrate by method similarly to Example 6, give bendability.Now, ferritic sheet is the quadrangle of length of side 2mm, is roughly uniform shape.The magnetic susceptibility of this sheet material is μ r ' is 84, μ r " be 0.4.
Use the two-sided tape of thickness 50 μm (goods name 467MP, Sumitomo 3M Co., Ltd. manufactures) to paste the face that conductive layer is not set of conductive ring antenna and sintered ferrite substrate, make Anneta module in mode not interstitial on binding face.Because the resonance frequency of this module is 10.8MHz, Q is 68, so be connected in parallel capacitor on coil antenna, make the capacitance variations of capacitor, adjust, make resonance frequency be 13.5 ~ 13.6MHz.After adjusting frequency, Q is 64.Make the conductor planes of this Anneta module and the iron plate contiguity of thickness 1mm, measure resonance characteristics.Whether its result, and install iron plate haveing nothing to do, and do not observe the change of resonance characteristics.
[embodiment 8]
In the Anneta module be made by method similarly to Example 7, the conductive layer of sintered ferrite substrate is, coating nickel-acrylic compounds electrically-conducting paint (trade name DotiteFN-101), drying 30 minutes at 50 DEG C, coating thickness is 10 μm, sheet resistance is 2 Ω/, in addition, carries out evaluation similarly to Example 7.Its result, resonance characteristics is resonance frequency be 13.6MHz, Q is 60, and whether installs iron plate haveing nothing to do, and does not almost observe change.
[embodiment 9]
Be provided with in use and print lamination conduction silver paste and the sintered ferrite substrate of the conductive layer of 10 μm integrally fired at 900 DEG C on raw cook, in addition, in the Anneta module be made by method similarly to Example 7, evaluation is similarly to Example 7 carried out.The sheet resistance of conductive layer is 0.1 Ω/, and resonance characteristics is resonance frequency be 13.55MHz, Q is 66, and whether installs iron plate haveing nothing to do, and does not almost observe change.
[comparative example 6]
Sintered ferrite substrate does not arrange conductive layer, in addition forms Anneta module by method similarly to Example 7.Not having resonance frequency during lamination iron plate to be 13.55MHz, Q is 67.Similarly to Example 7, measure resonance characteristics to the iron plate of its laminated thickness 1mm, resonance frequency becomes 11.5MHz, to lower frequency side skew 2MHz.Q is 67, and resonance degree does not change, but because frequency shift (FS), so do not produce resonance at 13.56 mhz, result communication strength significantly reduces.
[comparative example 7]
Adopting the structure same with comparative example 6, except 300 μm, carrying out the evaluation same with comparative example 6 except being set as by the thickness of sintered ferrite substrate.If lamination iron plate, then resonance frequency is 12.5MHz, and frequency change is less compared with comparative example 6, but communication strength reduces.
[comparative example 8]
In the Anneta module be made by method similarly to Example 7, the thickness being arranged on the conductive layer on sintered ferrite substrate is 5 μm, its sheet resistance is 5 Ω/, evaluates the resonance characteristics of the Anneta module of the structure in addition adopted similarly to Example 7.Its result, if lamination iron plate, then variation of resonant frequency is that the communication strength of 10.9MHz, 13.56MHz also reduces.
[embodiment 10]
By 1000 weight portions be adjusted to accumulation 50% particle volume diameter be 0.7 μm Mg-Zn-Cu ferrite powder (composition: Fe
2o
3: 48.5Mol%, MgO:27.0Mol%, ZnO:14.5Mol%, CuO:10.0Mol%, firing condition: 850 DEG C 180 minutes) carry out by the titante coupling agent (Ajincomoto Co., Inc manufacture KR-TTS) of 10 weight portions ferrite powder 1000 weight portion that surface treatment obtains, and thermoplastic elastomer (TPE) (TOSOH Co., Ltd. manufactures LUMITAC22-1) 50 weight portions, density 0.9g/cm
3polyethylene 100 weight portion, stearic acid 20 weight portion, with pressurization mixer at 130 DEG C mixing 40 minutes.Sandblasting is used to be processed into the iron plate that center line average roughness (Ra) is 450nm, maximum height (Rmax) is 8 μm, at temperature 160 DEG C, pressure 100kg/cm
2, 3 minutes pressing times condition under, mixing thing is formed to the ferrite resin obtained and carries out press molding, make that thickness is 74 μm, size is the molded ferrite sheet of the quadrangle of length of side 100mm.
By overlapping 10 of the molded ferrite sheet obtained.Clamped up and down as on the aluminium oxide setter (Kikumizu Chemical Industry Co., Ltd.'s manufacture) firing base, at 500 DEG C, degreasing 10 hours, fires 2 hours at 940 DEG C.Peel off sinter after cooling, plate can not have easily to be stripped damagedly.
The thickness of the sintered ferrite substrate obtained is 60 μm, and overall dimension is the quadrangle of length of side 80mm.The test film of external diameter φ 14mm, internal diameter φ 8mm is cut out from this sintered plate, use impedance analyzer E4991A (AgilentTechnologies (strain) manufacture) and be installed on the fixture (16454A) of its testboard, magnetic susceptibility when obtaining frequency 13.56MHz is μ r ' is 161, μ r " be 48, there is no set and the sintered ferrite substrate had excellent magnetic characteristics.
The surface roughness of the molded ferrite sheet obtained is, center line average roughness (Ra) is 380nm, maximum height (Rmax) is 4.8 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 38%.
In addition, the surface roughness of sintered ferrite substrate is, center line average roughness (Ra) is 366nm, maximum height (Rmax) is 4.1 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 31%.
[embodiment 11]
Using Mg-Zn-Cu ferrite 100 weight portion identical with embodiment 10 and BPBG 2 weight portion, polyvinyl alcohol resin (Sekisui Chemical Co., Ltd manufactures S-LECBBM-1) 12 weight portions, be mixed into n-butanol 4 as solvent: solvent 60 weight portion of toluene 6; with ball mill mixing, dissolving, dispersion, obtain ferrite dispersion paints.After by oily rotary vacuum pump decompression de-bubble being carried out to ferrite dispersion paints, utilize in one side, scraper to be become by blasting treatment that center line average roughness (Ra) is 530nm, maximum height (Rmax) is that the PET film (Panac Industrial Co., Ltd manufactures Le ミ マ Star ト 50S200 ト レ ス) of 5.6 μm carries out certain thickness coating, in 100 DEG C of hot blasts, drying 30 minutes, obtains the molded ferrite sheet of thickness 210 μm.
The molded ferrite sheet obtained is cut into the size of the quadrangle of length of side 100mm, peel off from PET film, under the condition identical with embodiment 10, the sheet material obtained is fired.
Carry out the evaluating characteristics of the sintered ferrite substrate obtained, result, thickness is 174 μm, and overall dimension is the quadrangle of length of side 80mm, magnetic susceptibility during 13.56MHz is μ r ' is 158, μ r " be 33, there is no set, easily peel off.
The surface roughness of the molded ferrite sheet obtained is, center line average roughness (Ra) is 450nm, maximum height (Rmax) is 5.1 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 40%.
The center line average roughness (Ra) of the opposing face in the face contacted with PET film, maximum height (Rmax) be respectively 131nm, 1.8 μm, the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 97%, the known PET film can passing through to use, control surface roughness wittingly.
In addition, the surface roughness of sintered ferrite substrate is, center line average roughness (Ra) is 338nm, maximum height (Rmax) is 3.6 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 21%.
[embodiment 12]
Accumulation 50% particle volume diameter mixing 300 weight portions is the Mg-Zn-Cu ferrite powder of 6 μm (composition: Fe
2o
3: 48.5Mol%, MgO:27.0Mol%, ZnO:14.5Mol%, CuO:10.0Mol%, firing condition: 1000 DEG C 180 minutes), Mg-Zn-Cu ferrite with accumulation 50% particle volume diameter identical with embodiment 10 of 700 weight portions is 0.7 μm, in addition obtains ferrite resin by method similarly to Example 10 and forms mixing thing.The iron plate that center line average roughness (Ra) is 120nm, maximal roughness is 2 μm is processed in use, at temperature 160 DEG C, pressure 100kg/cm
2, 3 minutes pressing times condition under, press molding is carried out to the mixing thing obtained, make thickness 188 μm, overall dimension 100mm molded ferrite sheet.
Carry out the evaluation processing the sheet material obtained and the sintered ferrite substrate obtained under the condition identical with embodiment 10.Its result, thickness is 157 μm, magnetic susceptibility during 13.56MHz is μ r ' is 144, μ r " be 21, there is no set, easily peel off.
The surface roughness of the molded ferrite sheet obtained is, be mixed with ferrite oversize grain, center line average roughness (Ra) is 361nm, maximum height (Rmax) is 6.2 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 67%.
In addition, the surface roughness of sintered ferrite substrate is, center line average roughness (Ra) is 305nm, maximum height (Rmax) is 4.0 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 49%.
[embodiment 13]
Except obtain the condition of the molded ferrite sheet of thickness 43 μm when applying with scraper except, obtain sintered ferrite substrate by method similarly to Example 11.
Carry out the evaluating characteristics of the sintered ferrite substrate obtained, result, thickness is 37 μm, magnetic susceptibility during 13.56MHz is μ r ' is 156, μ r " be 31, there is no set, easily peel off.
The surface roughness of the molded ferrite sheet obtained is, center line average roughness (Ra) is 345nm, maximum height (Rmax) is 4.0 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 23%.
In addition, the surface roughness of sintered ferrite substrate is, center line average roughness (Ra) is 289nm, maximum height (Rmax) is 3.1 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 12%.
[embodiment 14]
Except obtain the condition of the molded ferrite sheet of thickness 377 μm when applying with scraper except, obtain sintered ferrite substrate by method similarly to Example 11.
Carry out the evaluating characteristics of the sintered ferrite substrate obtained, result, thickness is 326 μm, magnetic susceptibility during 13.56MHz is μ r ' is 167, μ r " be 50, there is no set, easily peel off.
The surface roughness of the molded ferrite sheet obtained is, center line average roughness (Ra) is 634nm, maximum height (Rmax) is 7.8 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 66%.
In addition, the surface roughness of sintered ferrite substrate is, center line average roughness (Ra) is 593nm, maximum height (Rmax) is 7.8 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 39%
[comparative example 9]
Make ferrite resin by method similarly to Example 10 and form mixing thing, use is processed into the iron plate that center line average roughness (Ra) is 120nm, maximal roughness is 2 μm and is clamped constituent and form, and in addition makes sintered ferrite substrate under identical condition.Its result, set is serious, peels off difficulty, although a part can be peeled off, palette ruptures, and fails the sintered ferrite substrate of the quadrangle producing one piece of length of side 80mm.The magnetic susceptibility during 13.56MHz of sintered ferrite substrate is μ r ' is 160, μ r " be 48.
The surface roughness of the molded ferrite sheet obtained is, center line average roughness (Ra) is 98nm, maximum height (Rmax) is 0.9 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 5%.
In addition, the surface roughness of sintered ferrite substrate is, center line average roughness (Ra) is 81nm, maximum height (Rmax) is 0.8 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 1%.
[comparative example 10]
Ferrite dispersion paints is made by method similarly to Example 11.In the PET film of not carrying out sandblasting processing, (center line average roughness (Ra) is 17nm, maximum height (Rmax) is 0.3 μm, thickness is 50 μm) on, with scraper, certain thickness coating is carried out to the coating obtained, in 100 DEG C of hot blasts, drying 30 minutes, obtains the molded ferrite sheet of thickness 217 μm.
This sheet material is peeled off and overlapping 10 from PET film, carries out identical with embodiment 10 firing process, carry out the evaluation of the sintered ferrite substrate obtained.Thickness is 177 μm, and set is serious, can not peel off.
The surface roughness of the molded ferrite sheet obtained is, center line average roughness (Ra) is 78nm, maximum height (Rmax) is 1.8 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 87%.
In addition, the surface roughness of sintered ferrite substrate is, center line average roughness (Ra) is 54nm, maximum height (Rmax) is 1.3 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 0.2%.
[comparative example 11]
After making sheet material by the method same with comparative example 10, from PET film releasing sheet, on the molded ferrite sheet face contacted with the face of film, by the Zirconium oxide powder (N. E. Chemcat Corp.'s manufacture) that brushing coating 50mg average grain diameter is 5 μm, carry out afterwards same with comparative example 10 firing process, carry out the evaluation of the sintered ferrite substrate obtained.
The magnetic susceptibility during 13.56MHz of the sintered ferrite substrate obtained is μ r ' is 157, μ r " be 31.But, confirm to there is the position that zirconia powder anchors at sintered ferrite substrate surface, when it is removed with brush, 4 pieces of plate fractures in 10 pieces.Coating and the removing operation of powder are very loaded down with trivial details, can not remove Zirconium oxide powder completely.
[comparative example 12]
Except use sandblasting is processed into, center line average roughness (Ra) is 1200nm, maximum height (Rmax) is except the iron plate of 14 μm, obtains sintered ferrite substrate by method similarly to Example 10.There is no set, peel off while plate can not be damaged.
The magnetic susceptibility during 13.56MHz of the sintered ferrite substrate obtained is μ r ' is 78, μ r " be 1, be the value that can not meet magnetic characteristic.This is because surface roughness is excessive, result increases in space on the cross section of sintered ferrite substrate, thus magnetic susceptibility reduces.
[comparative example 13]
Ferrite dispersion paints is made by method similarly to Example 11.Carrying out roughness processing, center line average roughness (Ra) is 252nm, maximum height (Rmax) is in the PET film (TeijinDuPontFilms Co., Ltd. manufactures U4-50) of 3.3 μm, with scraper, certain thickness coating is carried out to the coating obtained, in 100 DEG C of hot blasts, drying 30 minutes, obtains the molded ferrite sheet of thickness 198 μm.
This sheet material is peeled off and overlapping 10 from PET film, carries out identical with embodiment 10 firing process, carry out the evaluation of the sintered ferrite substrate obtained.
The thickness of the sintered ferrite substrate obtained is 169 μm, and set is serious, can not peel off.
The surface roughness of the molded ferrite sheet obtained is, center line average roughness (Ra) is 246nm, maximum height (Rmax) is 2.6 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 97%.
In addition, the surface roughness of sintered ferrite substrate is, center line average roughness (Ra) is 201nm, maximum height (Rmax) is 2.1 μm, and the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 96%.
That is, from this result, in order to pursue effect of the present invention, be not only surface roughness, the control of the area ratio/occupancy ratio of the plane of disruption is also very important.
Result table of induction is shown in table 2.
[table 2]
[embodiment 15]
The concavo-convex machined surface of the sintered ferrite substrate obtained by embodiment 10 is pasted the two-sided tape (goods name 467MP, Sumitomo 3M manufacture) of thickness 50 μm, makes by 60 μm, sintered ferrite substrate layer and adhesive linkage 50 μm of laminated body formed.
In order to make this laminated body, there is bendability, be loaded in thickness 10mm, expansion ratio is about on the polyurethane sheet of 10 times, use the rubber rollers that profile is about 50mm, width is about 15cm, be about the pressure of 1kg/cm respectively to the longitudinal and transverse pressurization of laminated body with roller linear pressure, crack is set in sintered ferrite substrate entirety.
Then, stamping-out becomes profile 14mm φ, internal diameter 8mm φ, measures magnetic susceptibility.Magnetic susceptibility when 13.56MHz is that μ r ' is 121, μ r " be 10.
In addition, after above-mentioned laminated body being wound into the iron staff of profile 30mm φ, cut out test film similar to the above, measure magnetic susceptibility.Consequently μ r ' be 120, μ r " be 10, have almost no change, bendability is good, and magnetic susceptibility μ r ' is more than 80, also well
[embodiment 16]
The PET film being produced on 25 μm is provided with the flat plane antenna of the Vorticose conducting ring of 7 circle.The shape of its annular is the rectangle of vertical 45mm, horizontal 75mm.
In addition, use the Mg-Zn-Cu ferrite used in embodiment 10, the molded ferrite sheet of thickness 185 μm is made by method similarly to Example 11, utilize the Thomson cutter of each 30 ° of the point of a knife of V-type in shaping sheet surface, the V groove of the degree of depth about 90 μm is set with the clathrate being spaced apart 2mm.The molded ferrite sheet of the trough of belt obtained is cut into the quadrangle of length of side 100mm, peel off from PET film, under the condition identical with embodiment 10, the sheet material obtained is fired.
The thickness of the sintered ferrite substrate obtained is 143 μm, and overall dimension is the quadrangle of length of side 80mm.Do not have on the face of groove at sintered ferrite substrate, be coated in polyester resin electrically-conducting paint (the trade name DotiteXE-9000 being dispersed with silver and copper powders, Fujikura Kasei Co., Ltd manufactures), at 50 DEG C, drying 30 minutes, arranges the conductive layer of 30 μm.The sheet resistance of conductive layer is 0.2 Ω/.
This conducting surface is fitted after two-sided tape (goods name 467MP, Sumitomo 3M Co., Ltd. manufactures), cut ferrite sintered substrate by method similarly to Example 15, give bendability.Now, ferritic sheet is the quadrangle of length of side 2mm, is roughly uniform shape.The magnetic susceptibility of this sheet material is μ r ' is 119, μ r " be 9.0.
Use the two-sided tape of thickness 50 μm (goods name 467MP, Sumitomo 3M Co., Ltd. manufactures) to paste the face that conductive layer is not set of conductive ring antenna and sintered ferrite substrate, make Anneta module in mode not interstitial on binding face.Because the resonance frequency of this module is 15.5MHz, Q is 67, coil antenna is connected in parallel capacitor, makes the capacitance variations of capacitor, adjust, make resonance frequency be 13.5 ~ 13.6MHz.After adjusting frequency, do not observe the change of Q.Make the conductor planes of this Anneta module and the iron plate contiguity of thickness 1mm, measure resonance characteristics.Whether its result, and install iron plate haveing nothing to do, and do not observe the change of resonance characteristics.
[embodiment 17]
Making in the Anneta module obtained by method similarly to Example 16, the conductive layer of sintered ferrite substrate is, coating nickel-acrylic compounds electrically-conducting paint (trade name DotiteFN-101), drying 30 minutes at 50 DEG C, coating thickness is 10 μm, sheet resistance is 2 Ω/, in addition carries out evaluation similarly to Example 16.Its result, resonance characteristics is resonance frequency 13.6MHz, Q is 63, and whether installs iron plate haveing nothing to do, and does not almost observe change.
[embodiment 18]
Use to be provided with and on raw cook, to print lamination conduction silver paste and at the sintered ferrite substrate of 900 DEG C of conductive layers of 10 μm integrally fired, in addition, make Anneta module by method similarly to Example 16.To the evaluation that the Anneta module obtained carries out similarly to Example 16.The sheet resistance of conductive layer is 0.1 Ω/, and resonance characteristics is resonance frequency be 13.55MHz, Q is 63, and whether installs iron plate haveing nothing to do, and does not almost observe change.
[comparative example 14]
Sintered ferrite substrate does not arrange conductive layer, in addition, forms Anneta module by method similarly to Example 16.Not having resonance frequency during lamination iron plate to be 13.5MHz, Q is 66.Measure resonance characteristics to the iron plate of its laminated thickness 1mm similarly to Example 13, resonance frequency becomes 15.8MHz, to high frequency side skew 2.3MHz.Q is 66, and resonance degree does not change, but because frequency shift (FS), so do not produce resonance at 13.56 mhz, result, communication strength significantly reduces.
[comparative example 15]
Adopt the structure same with comparative example 14, the thickness of sintered ferrite substrate is set as 300 μm, in addition carries out the evaluation same with comparative example 14.If lamination iron plate, then resonance frequency is 13.9MHz, and frequency change is less compared with comparative example 14, but communication strength reduces.
[comparative example 16]
In the Anneta module be made by method similarly to Example 16, the thickness being arranged on the conductive layer on sintered ferrite substrate is 5 μm, its sheet resistance is 5 Ω/ couple, and the resonance characteristics being in addition the Anneta module of same structure with embodiment 7 is evaluated.Its result, if lamination iron plate, then resonance frequency becomes 15.0MHz, and communication strength during 13.56MHz also reduces.
Embodiment is more than used to further illustrate details for the present invention, but the regulation of number range of the present invention, certainly be also included within do not depart from purport of the present invention scope in, use the numerical value of above-mentioned arbitrary embodiment as whole scope regulation of critical value, should be understood to be recorded in this specification.
Claims (17)
1. thickness is the molded ferrite sheet of 30 μm ~ 430 μm, it is characterized in that:
In the surface roughness at least one surface, center line average roughness is 170nm ~ 800nm, and maximum height is 3 μm ~ 10 μm, the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 10 ~ 80%
By firing Ni-Zn-Cu spinel-like ferrite or Mg-Zn-Cu spinel-like ferrite and being formed,
When using Ni-Zn-Cu spinel-like ferrite powder, be Fe
2o
3the composition of be 40 ~ 50Mol%, NiO be 10 ~ 30Mol%, ZnO to be 10 ~ 30Mol%, CuO be 0 ~ 20Mol%, when using Mg-Zn-Cu spinel-like ferrite powder, is Fe
2o
3the composition of be 40 ~ 50Mol%, MgO be 15 ~ 35Mol%, ZnO to be 5 ~ 25Mol%, CuO be 0 ~ 20Mol%.
2. molded ferrite sheet as claimed in claim 1, is characterized in that:
Blasting treatment is utilized to carry out asperities processing to molded ferrite sheet surface.
3. molded ferrite sheet as claimed in claim 1, is characterized in that:
Surface Machining is utilized to become concavo-convex mould or felt wrapped roll to carry out press molding to molded ferrite sheet surface.
4. molded ferrite sheet as claimed in claim 1, is characterized in that:
When apply and dry ferrite dispersion paints to obtain shaping sheet material, the plastic film carrying out blasting treatment applies, transfer surface concavo-convex and obtain shaping sheet material.
5. molded ferrite sheet as claimed in claim 1, is characterized in that:
When apply and dry ferrite dispersion paints to obtain shaping sheet material, adjustment average grain diameter is the granularity of the ferrite powder of 0.1 ~ 10 μm, is provided with concavo-convex from the teeth outwards.
6. thickness is the sintered ferrite substrate of 25 μm ~ 360 μm, it is characterized in that:
In the surface roughness at least one surface, center line average roughness is 150nm ~ 700nm, and maximum height is 2 μm ~ 9 μm, the area ratio/occupancy ratio of the plane of disruption cut open in the horizontal direction at 50% depth of maximum height in 100 μm of square regions is 5 ~ 70%, is fired obtain by molded ferrite sheet according to claim 1.
7. sintered ferrite substrate as claimed in claim 6, is characterized in that:
Ferrite is Ni-Zn-Cu spinel-like ferrite, and the real part μ r ' of magnetic susceptibility during 13.56MHz is more than 80, the imaginary part μ r of magnetic susceptibility " be less than 20.
8. sintered ferrite substrate as claimed in claim 6, is characterized in that:
Ferrite is Mg-Zn-Cu spinel-like ferrite, and the real part μ r ' of magnetic susceptibility during 13.56MHz is more than 80, the imaginary part μ r of magnetic susceptibility " be less than 100.
9. sintered ferrite substrate as claimed in claim 6, is characterized in that:
The one side of sintered ferrite substrate is provided with conductive layer.
10. sintered ferrite substrate as claimed in claim 6, is characterized in that:
At least one side of sintered ferrite substrate is provided with groove.
11. sintered ferrite substrates as claimed in claims 6 or 7, is characterized in that:
At least one side of sintered ferrite substrate is pasted with adhesive film, and is provided with crack on sintered ferrite substrate.
12. 1 kinds of Anneta modules, it is the conductive ring Anneta module for wireless communication medium and wireless communication medium processing unit, the one side of magnetic part is provided with conductive ring antenna, and be provided with antenna magnetic part face opposing face on be provided with conductive layer, it is characterized in that:
Magnetic part is the sintered ferrite substrate described in claim 6 or 7.
13. Anneta modules as claimed in claim 12, is characterized in that:
The thickness of conductive layer is less than 50 μm, and sheet resistance is below 3 Ω/mouth.
14. Anneta modules as claimed in claim 12, is characterized in that:
Magnetic part is the ferrite sintered substrate of Ni-Zn-Cu spinel-like, and coating acrylic compounds or epoxies electrically-conducting paint are to arrange conductive layer.
15. Anneta modules as claimed in claim 12, is characterized in that:
Magnetic part is the ferrite sintered substrate of Mg-Zn-Cu spinel-like, coating acrylic compounds or
Epoxies electrically-conducting paint is to arrange conductive layer.
16. Anneta modules as claimed in claim 12, is characterized in that:
Magnetic part is the ferrite sintered substrate of Mg-Zn-Cu spinel-like, by utilizing silver paste carry out printing lamination and integrally fire on molded ferrite sheet, arranges conductive layer.
17. Anneta modules as claimed in claim 12, is characterized in that:
Magnetic part is the ferrite sintered substrate of Ni-Zn-Cu spinel-like, stacked and integrally fire by utilizing silver paste to carry out printing on molded ferrite sheet, arranges conductive layer.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
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| CN201610182890.1A CN105869820B (en) | 2007-03-07 | 2008-03-05 | Molded ferrite sheet, sintered ferrite substrate and Anneta module |
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| Application Number | Priority Date | Filing Date | Title |
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| JP2007057892 | 2007-03-07 | ||
| JP2007-057892 | 2007-03-07 | ||
| JP2007057892 | 2007-03-07 | ||
| JP2007282576A JP5194717B2 (en) | 2007-10-31 | 2007-10-31 | Ferrite molded sheet, sintered ferrite substrate and antenna module |
| JP2007282576 | 2007-10-31 | ||
| JP2007-282576 | 2007-10-31 |
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| Application Number | Title | Priority Date | Filing Date |
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| CN201610182890.1A Division CN105869820B (en) | 2007-03-07 | 2008-03-05 | Molded ferrite sheet, sintered ferrite substrate and Anneta module |
| CN201310409292.XA Division CN103496960B (en) | 2007-03-07 | 2008-03-05 | Molded ferrite sheet, sintered ferrite substrate and antenna module |
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| CN101262085A CN101262085A (en) | 2008-09-10 |
| CN101262085B true CN101262085B (en) | 2016-04-27 |
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| CN (1) | CN101262085B (en) |
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| KR101476044B1 (en) * | 2012-12-06 | 2014-12-23 | 쓰리엠 이노베이티브 프로퍼티즈 캄파니 | Ferrite Green Sheet, Sintered Ferrite Sheet, Ferrite Complex Sheet Comprising the Same, and Conductive Loop Antenna Module |
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| JP6832928B2 (en) * | 2015-11-11 | 2021-02-24 | アモテック・カンパニー・リミテッド | Ferrite sheet manufacturing method and ferrite sheet using this |
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| CN101262085A (en) | 2008-09-10 |
| JP2008252089A (en) | 2008-10-16 |
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