CN103956573A

CN103956573A - Method for manufacturing radar protection hood

Info

Publication number: CN103956573A
Application number: CN201410213964.4A
Authority: CN
Inventors: 钱苗根
Original assignee: HUZHOU TIAHE AUTOMOBILE PART Co Ltd
Current assignee: HUZHOU TIAHE AUTOMOBILE PART Co Ltd
Priority date: 2014-05-21
Filing date: 2014-05-21
Publication date: 2014-07-30
Anticipated expiration: 2034-05-21
Also published as: CN103956573B

Abstract

The invention relates to a method for manufacturing an early-warning system device for active collision prevention of automobiles, in particular to a manufacturing method of radar protection hood. The method sequentially comprises the steps of pre-processing, wherein an obtained substrate is dedusted and cleaned; hot stamping, wherein an area needing to be plated with a nanocrystalline metal layer in the next process is covered, and then a colored layer is printed on the substrate or arranged on the substrate in a hot stamping mode; the first time of plating, wherein the magnetron sputtering method or the vacuum evaporation method is used for plating a nano indium alloy layer on an area, not subjected to hot stamping or printing, around the colored layer, and the nanocrystalline metal layer which is 5-50 nm thick is formed; forming a coating protection layer through spraying and forming a reinforced layer through surface coating or vacuum plating. Metal ingredients of the nanocrystalline metal layer of the manufactured radar protection hood are selectively matched with plated layers, a mark of the radar protection hood has good metallic luster, millimeter waves emitted by a radar are made to have no attenuation when penetrating through the protection hood back and forth, and zero emission of heavy metal ions is achieved.

Description

A kind of preparation method of radar protective cover

Technical field

The present invention relates to a kind ofly for initiatively crashproof early warning system device of automobile, relate in particular to a kind of preparation method of radar protective cover.

Background technology

Traffic accident brings huge disaster, and research shows, more than 80% traffic accident is because driver's reaction is caused not in time.Automobile primary automatic collsion avoidance system is to provide warning message to driver in time before traffic hazard occurs, and can carry out to automobile the actions such as active is cruised, slowing-down brake, with respect to the passive anti-collision facility of automobile in the past, significantly reduce traffic safety hidden danger, reduce the harm that traffic accident brings.

Consider the factor such as orientation angles, signal strength signal intensity, trailer-mounted radar is generally all arranged on car medicephalic car mark inner side place.Common car mark only has good mark effect, but can not be as the protective cover of trailer-mounted radar, and this is because general metal material or electroplating surface metal layer all can make the millimeter wave of radar emission that serious decay occurs, or can not be back and forth by car mark.

Prior art is a kind of radome for vehicle radar system and manufacture method thereof as patent EP1750329A1 discloses, insulation lens are installed on the first contact-making surface of this radome, and the insulation lens in radome can be arranged on the contact-making surface of radome by bonding connection or welding manner.This patent is mainly used in solving the existing vehicle radar system large problem that takes up room.

Patent CN1838482B provides a kind of metallic luster layer decorative molded article of the course of the beam for radar installations, comprise the matrix being formed by transparent resin layer, be arranged on tin and/or ashbury metal layer on the back side of this matrix, and be arranged on the decoration enamelled coating on the back side of this tin and/or ashbury metal layer.Described in this patent, formed products has the exquisite metal designs of the tones such as similar chromium plating, and can not hinder the transmission of radio wave.

But the device of above-mentioned patent is difficult to take into account transporting and the manufacturability of radio wave, can not provide simultaneously one both had that good metal-like, enough intensity, unfailing performance are good, the radar protective cover of long service life and minimum on the impact of radar electromagnetic wave, not affect radar performance performance.

Summary of the invention

The object of this invention is to provide and a kind ofly can make the mark of radar protective cover there is good metallic luster, can make again the millimeter wave energy of radar emission pass through back and forth the preparation method of this protective cover and the little radar protective cover of attenuation rate.

Technical purpose of the present invention is achieved by the following technical programs:

A preparation method for radar protective cover, is characterized in that comprising successively step:

(1) pre-treatment: pre-treatment gained substrate is carried out to dedusting clean;

(2) thermoprint: the region of covering next procedure and wanting plating nano-metal layer, then thermoprint or be printed with chromatograph on substrate;

(3) plating for the first time: adopt magnetron sputtering method or vacuum vapour deposition described nonferrous layer around not the region of thermoprint or printing be coated with nanometer indium alloy layer, the nano metal layer that formation thickness is 5-50nm;

(4) spraying and curing: spray UV paint or PU paint on described nano metal layer, formation coating protection layer after solidifying;

(5) face is coated with or Vacuum Deposition: on another surface of described substrate, spray UV paint or PU paint or vacuum coating and form reinforced layer.

Preparation method's of the present invention advantage is:

(1) form adjacent successively coating protection layer, nano metal layer, nonferrous layer, prime coat, substrate and reinforced layer by the each step preparation of the present invention especially twice special Vacuum Deposition, make the mark of radar protective cover there is good metallic luster, possess the mark effect that car mark is good; Make radar millimeter wave be close to undamped simultaneously; Also make in addition radar not be subject to the infringement of the extraneous natural causes such as dust storm sleet and light, thereby play a good protection; In serviceability, there is good case hardness, intensity and decay resistance, useful life is for 20 years;

(2), if nano metal tunic layer is too thin, be difficult to ensure that its surface has good metallic luster; Rete is too thick, can make the attenuation rate of radar millimeter wave raise, and is difficult to ensure the validity that radar uses, and the thickness of nano metal layer of the present invention can balance and the performance requirement of the face of coordinating all quarters concerned, and makes radar protective cover possess good combination property.

As preferably, described step (1) pre-treatment, specifically first to substrate electrostatic precipitation, is then used hairbrush dedusting, finally adopts Dry ice cleaning.

By in and piece surface static, with high velocity gas stream piece surface dust, and then adopt hairbrush particularly ostrich mao mao brush act mechanically on piece surface, by disturbance souring, piece surface dust is departed from, and taken away by air-flow, finally adopt dry ice to clean injection molding body, pre-treatment is carried out thoroughly, to ensure the quality of plated film.

As preferably, the region that described step (2) is covered next procedure and wanted plating nano-metal layer, then black film or the colored film layer of thermoprint or printing 0.1-1 micron thickness on substrate.

As preferably, described step (3) nanometer indium alloy is indium and accounts for one or more of tin that mass percent is 0-10%, gallium, silver, germanium.

The metal ingredient of nano metal layer is selected and each coating mating reaction, can make the mark of radar protective cover have good metallic luster, almost undamped can make again the millimeter wave of radar emission pass through back and forth this protective cover time, has ensured the validity that radar uses; And can realize product environmental requirement, reach heavy metal ion zero discharge.

More preferably, described nanometer indium alloy is the indium alloy containing 5wt% silver.

This composition can make radar protective cover have very little radar Attenuation rate and good metallic luster.

Further preferably, the technique that adopts vacuum vapour deposition to be coated with described nano metal layer is to be (1-2) × 10 in vacuum degree ^-2under the vacuum degree of Pa, carry out continuously three phases evaporation, first stage evaporation is to evaporate 10-12s under 1.5-2.5 volt, and second stage evaporation is to evaporate 6-10s under 3.5-4.5 volt, and the phase III is to evaporate 3-4s under 5.5-6.5 volt.

Adopt this technological parameter, can ensure specific thickness and the repeatability of rete, obtain very high sheet resistance and island membrane structure, thereby the attenuation rate can make millimeter wave pass through film time is reduced to very little degree; And ensure gloss and the brightness of metallic film simultaneously, meet the requirement of functional mark.

More preferably, described indium and silver-colored purity are 99.99%.

The control of purity makes the mark of radar protective cover have better metallic luster, possesses the mark effect that car mark is good; Make radar millimeter wave be close to undamped simultaneously.

Preferably, described step (3) adopt magnetron sputtering method or vacuum vapour deposition form island structure, thickness is the nanometer indium alloy layer that 5-50nm and sheet resistance are greater than 20 megaohms/.

Applicant finds: nano metal layer is blocked up and sheet resistance is too small, is difficult to make radar wave to pass through with very little attenuation rate, can not ensure the validity that radar uses; Rete is too thin, is difficult to ensure that it has good metallic luster; Rete is too thick, can make the attenuation rate of radar millimeter wave raise; Sheet resistance size and thicknesses of layers select must with each coating mating reaction, could both make the mark of radar protective cover there is good metallic luster, almost undamped can make again the millimeter wave of radar emission pass through back and forth this protective cover time, ensure the validity that radar uses; And can realize product environmental requirement, reach heavy metal ion zero discharge.

As preferably, described in being also included in, described preparation method after plating, plates for the second time for the first time: adopt intermediate frequency twin-target sputtering method or electron beam vacuum vapour deposition to be coated with oxide film on described nano metal layer, form protective oxide film.

The composition of described protective oxide film and thickness contribute to protect nano metal layer, can make the mark of radar protective cover there is better metallic luster, almost undamped can make again the millimeter wave of radar emission pass through back and forth this protective cover time, ensure the validity that radar uses; Thereby make radar protective cover possess good combination property.

More preferably, described oxide film is silica membrane.

More preferably, the method that adopts vacuum vapour deposition to be coated with described silica membrane is with electron beam vacuum evaporation, the evaporation source adopting comprises electron gun, field coil and crucible, and described electron gun comprises the anode of the filament of electron emission, the focusing electrode that converges electronics and acceleration electronics; Described field coil and accelerating field are perpendicular.

Be polycarbonate because product of the present invention is base materials employed, when vacuum coating, vacuum indoor temperature or particle bombardment energy can not be too high, and protective oxide film raw material used often have high fusing point, therefore must select suitable technique.

Taking electron beam vacuum evaporation silica membrane as example, evaporation source adopts e type electron gun, i.e. 270 ° of deflection of a beam of electrons make beam bombardment to the silicon dioxide coating materials in crucible, have avoided the pollution of electron gun filament material to coating materials.

Electron Beam Focusing characteristic depends on filament (negative electrode), converges shape, relative position and the added voltage of the focusing electrode of electronics and these three electrodes of anode of acceleration electronics.Filament (negative electrode) is generally manufactured by tungsten filament, connects low-voltage and high-current, tungsten filament can be heated to the thermionic incandescent state of transmitting.

Described field coil and accelerating field are perpendicular, after electronics is accelerated, be subject to the effect of the Loulun magnetism that crossed electric and magnetic field produces, change the direction of motion, electron beam trace becomes zigzag shape, and beam shapes is as English words e, and the magnetic field that field coil produces makes electronic deflection to crucible, regulate the large I of field supply to change magnetic field intensity, reach the lip-deep position of evaporating materials (coating materials) thereby can change electron beam.

Further preferably, the negative pole of the filament parallel high pressure accelerating power source of electron gun, voltage is 6-30KV, and electronics accelerated motion under high voltage electric field effect forms electron beam, and line is 0.3-1A.

Further preferably, described crucible is oxygen-free copper crucible.

In the assembly in electron gun evaporation source, crucible is also pith.Adopt oxygen-free copper crucible, water flowing is cooling, in crucible, can place different coating materials, can change bushing position by inversion mechanism.

Further preferably, the method that adopts vacuum vapour deposition to be coated with described silica membrane is;

1. substrate and coating materials are put into vacuum chamber, close door for vacuum chamber, be evacuated to (5-8) × 10 ^-3pa;

2. open magnetic field power supply, be transferred to predetermined field supply, determine magnetic field intensity, to ensure that electron beam can get on crucible;

3. open filament heating power supply, heat filament;

4. the high pressure accelerating power source of unlocking electronic rifle, voltage is transferred to 6-30KV;

5. regulate heating current and the field supply of filament, make beam spot be positioned at crucible central authorities;

6. regulate line scanning monitor, with x-y transverse and longitudinal bi-directional drive line, and adjusting amplitude and frequency;

7. steam coating silicon dioxide film under the parameter of accelerating voltage 6-30KV, line 0.3-1A, deposition rate 0.3-0.4nm/s;

8. with the deposit thickness of quartz crystal vibration thickness instrument control silica membrane processed, during to 100-150nm, plated film finishes.

Still more preferably, in silica deposit process, adopt ion beam assisted depositing method to improve density and the adhesive force of silica membrane, specifically:

A. in vacuum chamber, place ion source, operating current 16-20A, discharge power 100-150W, working gas is argon gas;

B. the ar-ion beam that ion beam assisted depositing ion beam energy used is 400-800ev first bombards 1-5min with described ar-ion beam to described substrate before plated film, described substrate surface is cleaned and activation;

C. in cvd silicon dioxide film, with the ar-ion beam bombardment deposition surface of 400-800ev;

D. with the deposit thickness of quartz crystal vibration thickness instrument control silica membrane processed, during to 100-150nm, plated film finishes.

In cvd silicon dioxide film, with the ar-ion beam bombardment deposition surface of 400-800ev; By momentum interchange and the intermixing of ion and film forming atom, thereby significantly improve density and the adhesive force of silica coating.

Because atom or molecule energy in the time depositing of thermal evaporation are very low; be about 0.2ev; its surface mobility is also just very low; add that the atom or the molecule that have deposited can cause hatching effect to the atom or the molecule that deposit afterwards; evaporated film is and contains more mushy cylindrical particle aggregate structure, the protective effect of silica membrane significantly reduces.Therefore in silica membrane process, adopt ion beam assisted depositing method (Ion beam assisted deposition, writes a Chinese character in simplified form IBAD), can significantly improve silica membrane density and adhesive force, thereby greatly strengthen the protective effect of silica membrane.

As preferably, UV paint or PU paint that described step (4) sprays 10-25 micron thickness on described protective oxide film form coating protection layer; The UV paint or the PU paint that on another surface of described substrate, spray 10-25 micron thickness form reinforced layer simultaneously.

More preferably, described step (4) also comprises that the UV paint of spraying is carried out to UV-irradiation to be solidified.

As preferably, described preparation method toasts before being also included in pre-treatment step.

By baking, priming coat prepared by base material and subsequent technique and finishing coat have better adhesion.

As preferably, described radar protective cover also comprises the base that is arranged on described substrate rear, and described substrate and described base are polycarbonate plate, and described substrate and described base are combined closely by dotting glue method.

Adopt conventional method to make protecgulum and understructure easily make product entirety bonding, easily occur substandard products, and it is influenced to adopt dotting glue method of the present invention can not affect each layer of structure of protecgulum, performance and the qualification rate of raising product.

As preferably, described preparation method also comprises material handle milling unnecessary on substrate injection body is removed.

Of the present inventionly also provide a kind of and can make the mark of radar protective cover there is good metallic luster, can make again the millimeter wave energy of radar emission pass through back and forth this protective cover and the little radar protective cover of attenuation rate.

This object is achieved by following four kinds of technical schemes:

The first technical scheme is:

A kind of radar protective cover; comprise the substrate with front surface and rear surface; on the front surface of described substrate, be coated with reinforced layer; described in it, on the rear surface of substrate, from-inner-to-outer is at least coated with prime coat, nonferrous layer, nano metal layer and coating protection layer, and the metal ingredient of described nano metal layer is indium and accounts for one or more of tin that mass percent is 0-10%, gallium, silver, germanium.

The present invention is with orientation, trailer-mounted radar place for below, and the rear surface of described substrate is towards trailer-mounted radar.

Advantage of the present invention is:

(1) adjacent coating protection layer, nano metal layer, nonferrous layer, substrate and reinforced layer successively, makes the mark of radar protective cover have good metallic luster, possesses the mark effect that car mark is good; Make radar millimeter wave be close to undamped simultaneously; Also make in addition radar not be subject to the infringement of the extraneous natural causes such as dust storm sleet light, thereby play a good protection; In serviceability, reinforced layer has strengthened again the performance of substrate, and the outer surface of giving radar protective cover has good ageing resistance, case hardness, intensity and decay resistance, and useful life is for 20 years;

(2) metal ingredient of nano metal layer is selected and each coating mating reaction, can make the mark of radar protective cover there is good metallic luster, almost undamped can make again the millimeter wave of radar emission pass through back and forth this protective cover time, ensure the validity that radar uses; And can realize product environmental requirement, reach heavy metal ion zero discharge.

As preferably, the metal ingredient of described nano metal layer is the indium alloy containing 5wt% silver.

This composition makes radome have very little radar Attenuation rate and good metallic luster.

More preferably, described indium and silver-colored purity are 99.99%.

More preferably, the thickness of described nano metal layer is 5-50nm.

Rete is too thin, is difficult to ensure to have good metallic luster; The too thick attenuation rate that can make radar millimeter wave of rete raises, and is difficult to the validity that ensures that radar uses.And the thickness of nano metal layer of the present invention can balance and the performance requirement of the face of coordinating all quarters concerned, and makes radar protective cover possess good combination property.

As preferably, the sheet resistance of described nano metal layer is greater than 20 megaohms/.

If resistance is too little, be difficult to make radar wave to pass through with very little attenuation rate, can not ensure the validity that radar uses.

As preferably, described nano metal layer is island structure.

Applicant finds; adopt the nano metal layer of island structure can greatly reduce the attenuation rate of this radar millimeter wave; make to be close to undamped through the radar millimeter wave of this radar protective cover; this may be that the attenuation rate of radar millimeter wave is relevant with metal level resistance; and adopt island structure can greatly improve the resistance of this nano metal layer, thereby not only made the mark of the radar protective cover of the nano metal layer with island structure have good metallic luster, but also make the millimeter wave energy of radar emission pass through back and forth this protective cover and attenuation rate little.

When island structure of the present invention is nano metal layer employing vapor deposition film, first in substrate, form critical nuclei, in the time that atom constantly deposits, core is grown up with three-dimensional, not only increase but also expand, forming island, also there will be new core to continue to grow up into island simultaneously.In the time that island constantly expands in substrate, island can be linked to each other, and forms the passage on island.Island structure is a kind of discontinuous membrane structure.

As preferably, on described substrate, be also coated with the protective oxide film being arranged between described nano metal layer and described coating protection layer.

More preferably, described protective oxide film is silica membrane, and thickness is 100-150nm.

The composition of described protective oxide film and thickness contribute to protect nano metal layer, can make the mark of radar protective cover there is good metallic luster, almost undamped can make again the millimeter wave of radar emission pass through back and forth this protective cover time, ensure the validity that radar uses; Thereby make radar protective cover possess good combination property.

As preferably, described reinforced layer is the UV paint of 10-25 micron thickness or the vacuum coating of PU paint or 100-200 nano thickness.

The present invention adopts UV paint or the PU paint of highly filled for example 70-95%, is sprayed on surface of the work, controls the thickness of reinforced layer simultaneously, makes reinforced layer have good case hardness, intensity and decay resistance.

More preferably, curing the forming of described UV paint employing UV-irradiation.

Through overcuring, reinforced layer has good adhesion, and wounded substrate not.

As preferably, described nonferrous layer is thermoprint black film or the printing color rete of 0.1-1 micron thickness.

Adopt thermoprint black film or the printing color rete of this thickness can make the mark of radar protective cover there is better metallic luster, in serviceability, there is better case hardness, intensity and decay resistance, make radar millimeter wave be close to undamped simultaneously.

As preferably, the UV paint that described coating protection layer is 10-25 micron thickness or PU paint.

As preferably, described radar protective cover also comprises by binding agent or quadric injection mould mode and the interconnective base of described substrate.

Described substrate is as car mark protecgulum, and described base is positioned at after car mark, so that protection covers the each coating on described substrate.

As preferably, described substrate and/or base are the shock proof plastic material of transparency and heat-proof.

More preferably, described substrate and/or base are polycarbonate substrate.

More preferably, the gross thickness of described substrate and base is 4.4-5.3mm.

The second technical scheme is:

A kind of radar protective cover; comprise the substrate with front surface and rear surface; on the front surface of described substrate, be coated with reinforced layer, described in it, on the rear surface of substrate, from-inner-to-outer is at least coated with nonferrous layer, nano metal layer and coating protection layer, and the thickness of described nano metal layer is 5-50nm.

Advantage of the present invention is:

(1) adjacent coating protection layer, nano metal layer, nonferrous layer, substrate and reinforced layer successively, makes the mark of radar protective cover have good metallic luster, possesses the mark effect that car mark is good; Make radar millimeter wave be close to undamped simultaneously; Also make in addition radar not be subject to the infringement of the extraneous natural causes such as dust storm sleet and light, thereby play a good protection; In serviceability, there is good case hardness, intensity and decay resistance, useful life is for 20 years;

(2) thickness of nano metal layer is selected and each coating mating reaction, can make the mark of radar protective cover there is good metallic luster, almost undamped can make again the millimeter wave of radar emission pass through back and forth this protective cover time, ensure the validity that radar uses; And can realize product environmental requirement, reach heavy metal ion zero discharge; And if nano metal tunic layer is too thin, although sheet resistance is very large, visible reflectance is low, and the luminance shortage of the metallic film that seems can not reach the requirement of functional mark; Rete is too thick, can make the attenuation rate of radar millimeter wave raise, and is difficult to the validity that ensures that radar uses; And the thickness of nano metal layer of the present invention can balance and the performance requirement of the face of coordinating all quarters concerned, and makes radar protective cover possess good combination property.

As preferably, the metal ingredient of described nano metal layer is indium and accounts for one or more of tin that mass percent is 0-10%, gallium, silver, germanium.

More preferably, the metal ingredient of described nano metal layer is the indium alloy containing 5wt% silver.

More preferably, described indium and silver-colored purity are 99.99%.

If resistance is too little, be difficult to make radar wave to pass through, can not ensure the validity that radar uses.

As preferably, described nano metal layer is island structure.

Applicant finds, adopts the nano metal layer of island structure can greatly reduce the attenuation rate of this radar millimeter wave, makes to be close to undamped through the radar millimeter wave of this radar protective cover.The attenuation rate of radar millimeter wave is relevant with metal level resistance; and adopt island structure can greatly improve the resistance of this nano metal layer, thereby not only made the mark of the radar protective cover of the nano metal layer with island structure have good metallic luster, but also make the millimeter wave energy of radar emission pass through back and forth this protective cover and attenuation rate little.

Adopt thermoprint black film or the printing color rete of this thickness can make the mark of radar protective cover there is more significant metallic luster, in serviceability, there is better case hardness, intensity and decay resistance, make radar millimeter wave be close to undamped simultaneously.

As preferably, UV paint or PU enamelled coating that described coating protection layer is 10-25 micron thickness.

Described substrate is as protecgulum, and described base is positioned at after car mark, so that protection covers the each coating on described substrate.

More preferably, described substrate and/or base are polycarbonate substrate.

The third technical scheme is:

A kind of radar protective cover; comprise the substrate with front surface and rear surface; on the front surface of described substrate, be coated with reinforced layer; described in it, on the rear surface of substrate, from-inner-to-outer is at least coated with nonferrous layer, nano metal layer and coating protection layer, and the sheet resistance of described nano metal layer is greater than 20 megaohms/.

Advantage of the present invention is:

(1) adjacent coating protection layer, nano metal layer, nonferrous layer, substrate and reinforced layer successively, makes the mark of radar protective cover have good metallic luster, possesses the mark effect that car mark is good; Make radar millimeter wave be close to undamped simultaneously; Also make in addition radar not be subject to the infringement of the extraneous natural causes such as dust storm sleet light, thereby play a good protection; In serviceability, there is good case hardness, intensity and decay resistance, useful life is for 20 years;

(2) if the sheet resistance of nano metal layer is too little, be difficult to make radar wave to pass through with very little attenuation rate, can not ensure the validity that radar uses; Sheet resistance size is selected and each coating mating reaction, can make the mark of radar protective cover have good metallic luster, almost undamped can make again the millimeter wave of radar emission pass through back and forth this protective cover time, has ensured the validity that radar uses; And can realize product environmental requirement, reach heavy metal ion zero discharge.

More preferably, described indium and silver-colored purity are 99.99%.

As preferably, the thickness of described nano metal layer is 5-50nm.

Rete is too thin, is difficult to ensure that it has good metallic luster; Rete is too thick, can make the attenuation rate of radar millimeter wave raise, and is difficult to ensure the validity that radar uses, and the thickness of nano metal layer of the present invention can balance and the performance requirement of the face of coordinating all quarters concerned, and makes radar protective cover possess good combination property.

As preferably, described nano metal layer is island structure.

Applicant finds: adopt the nano metal layer of island structure can greatly reduce the attenuation rate of this radar millimeter wave; make to be close to undamped through the radar millimeter wave of this radar protective cover; this may be that the attenuation rate of radar millimeter wave is relevant with metal level resistance; and adopt island structure can greatly improve the resistance of this nano metal layer, thereby not only made the mark of the radar protective cover of the nano metal layer with island structure have good metallic luster, but also make the millimeter wave energy of radar emission pass through back and forth this protective cover and attenuation rate little.

More preferably, described substrate and/or base are polycarbonate substrate.

The 4th kind of technical scheme is:

A kind of radar protective cover; comprise the substrate with front surface and rear surface; on the front surface of described substrate, be coated with reinforced layer, described in it, on the rear surface of substrate, from-inner-to-outer is at least coated with nonferrous layer, nano metal layer and coating protection layer, and described nano metal layer is island structure.

Applicant finds:

(1) adopt the nano metal layer of island structure can greatly reduce the attenuation rate of this radar millimeter wave, make to be close to undamped through the radar millimeter wave of this radar protective cover, this may be that the attenuation rate of radar millimeter wave is relevant with metal level resistance, and adopt island structure can greatly improve the resistance of this nano metal layer, thereby not only made the mark of the radar protective cover of the nano metal layer with island structure have good metallic luster, but also make the millimeter wave energy of radar emission pass through back and forth this protective cover and attenuation rate little;

(2) adjacent coating protection layer, nano metal layer, nonferrous layer, substrate and reinforced layer successively, makes the mark of radar protective cover have good metallic luster, possesses the mark effect that car mark is good; Make radar millimeter wave be close to undamped simultaneously; Also make in addition radar not be subject to the infringement of the extraneous natural causes such as dust storm sleet light, thereby play a good protection; In serviceability, there is good case hardness, intensity and decay resistance, useful life is for 20 years.

More preferably, described indium and silver-colored purity are 99.99%.

As preferably, the thickness of described nano metal layer is 5-50nm.

As preferably, described substrate is as protecgulum, and described substrate and/or base are the shock proof plastic material of transparency and heat-proof.

More preferably, described substrate and/or base are polycarbonate substrate.

Brief description of the drawings

Fig. 1 is the schematic diagram of the each hierarchical structure of radar protective cover of the present invention and radar protective cover and radar bearing relation;

Fig. 2 is the radar protective cover preparation method's of one embodiment of the invention process route chart;

In figure, 1-substrate; 2-reinforced layer; 3-nonferrous layer; 4-nano metal layer; 5-protective oxide film; 6-coating protection layer; 7-base; R-radar.

Embodiment

Embodiment mono-

The radar protective cover of certain model automobile, comprises the substrate with front surface and rear surface.Baseplate material is the plastic material of transparency and heat-proof shock resistance, high comprehensive performance, for example polycarbonate plate.Two of substrate 1 surfaces are processed respectively, and the cross-section structure of this radar protective cover is shown in Fig. 1.

Reinforced layer 2 adopts highly filled UV paint or PU paint, is sprayed on surface of the work, and THICKNESS CONTROL is at 10 microns.UV paint need solidify by UV-irradiation.Reinforced layer 2 also can adopt vacuum coating preparation, to improve hardness and the resistance to wear of substrate 1.

Nonferrous layer 3 is thermoprint black film or printing color rete, is decided according to the actual requirements, and thickness is 0.1 micron.

Nano metal layer 4 is for containing 5%(quality) silver-colored indium alloy, indium and silver-colored purity are all 99.99%.This thicknesses of layers is 15 nanometers.Its effect is to have good metallic luster and visible reflectance, and when the millimeter wave of radar emission passes through this protective cover back and forth simultaneously, attenuation rate is very little.

Nano metal layer is very thin, and thickness is 15 nanometers, and the microstructure of rete, taking " island " structure as main, is a kind of discontinuous film, thereby ensures to have very high resistance, very little to the radar Attenuation rate of passing through back and forth.

The conductivity of film and electron mean free path λ _ft is relevant with thickness.At t < λ _ftime, if rete is island, resistivity is very big, when t increases to after tens nanometer, resistivity sharply declines; As t>=λ _ftime, the resistivity of film and body material approach, but larger than body material.

Protective oxide film 5 is silica membrane, and thickness is 100 nanometers, and its effect is mainly protection nano metal layer.

Coating protection layer 6 adopts highly filled UV paint or PU paint, is sprayed on surface of the work, and THICKNESS CONTROL is at 10 microns.UV paint need solidify by UV-irradiation.

Base 7 adopts the material composition of the high transmission identical with substrate 1, after surface treatment, interconnects by binding agent and substrate 1, and substrate 1 is 4.4mm with the thickness of base 7.

The manufacturing process of this product mainly contains injection moulding, pre-treatment, thermoprint, magnetron sputtering or vacuum evaporation coating, medium frequency twin-target sputtering method or electron beam vacuum vapour deposition, spraying or solidifies, puts glue, milling cast gate, inspection, packaging etc.Process route is shown in Fig. 2.

Injection moulding: open injection mold processed by product requirement, the injection molding machine of selected required clamp force, stepless speed regulation multipole injection molding.

Pass on and reach the standard grade: moulding, after part under manipulator, is placed on conveying belt and reaches the standard grade.

Baking: through baking, substrate and priming coat, finishing coat have better adhesion.

Pre-treatment: electrostatic precipitation, in and piece surface static, with high velocity gas stream piece surface dust, and then adopt hairbrush particularly ostrich mao mao brush act mechanically on piece surface, by disturbance souring, piece surface dust is departed from, and taken away by air-flow, finally adopt dry ice to clean injection molding body, guarantee workpiece cleans and enters next procedure.Pre-treatment is carried out thoroughly, influenced to prevent its case hardness, intensity and decay resistance, improve its useful life.

Thermoprint: the region that utilizes frock to cover next procedure to want plating nano-metal layer, then on substrate surface, scald black film or printing color rete.

Plating for the first time: by magnetron sputtering method or vacuum vapour deposition, be coated with nanometer indium alloy layer, strictly control its thickness and be greater than 20 megaohms/ in 15 nanometers and sheet resistance.

Resistance test adopts common universal instrument, 1 centimeter of test of spacing.

The factors such as definite and properties of product requirement, film plating process, filming equipment, coating materials composition, the thicknesses of layers of actual process parameter are relevant.

The indium silver alloy (coating materials) that now contains 5wt% silver taking vacuum evaporation, as example, illustrates the preparation technology of Vacuum Deposition nano metal layer.

1. coating materials: 1 millimeter of diameter, length 3-5 centimetre;

2. evaporation source: conic net basket tungsten hank knotting, 4;

3. work rest: 80 millimeters of workpiece (substrate) diameters, each plated film can be settled 8-12 workpiece, has public affairs, rotation, and rotating speed is electrodeless adjustable, and revolution speed is controlled at 4-6 rev/min;

4. filming equipment: 1600 millimeters of the diameters of vacuum chamber, 1200 millimeters of height;

5. vacuum evaporation process is to be 1.5 × 10 in vacuum degree ^-2under the vacuum degree of Pa, carry out continuously three phases evaporation, first stage evaporation is to evaporate 11s under 2 volts, and second stage evaporation is to evaporate 8s under 4 volts, and the phase III is to evaporate 3.5s under 6 volts.

Plating for the second time: by medium frequency twin-target sputtering method or electron beam vacuum vapour deposition, be coated with silica membrane, thickness is 100nm.

Be polycarbonate because product of the present invention is base materials employed, when vacuum coating, vacuum indoor temperature or particle bombardment energy can not be too high, and protective oxide film raw material Wang Wang used has high fusing point, therefore must select suitable technique.

Field coil and accelerating field are perpendicular, after electronics is accelerated, be subject to the effect of the Loulun magnetism that crossed electric and magnetic field produces, change the direction of motion, electron beam trace becomes zigzag shape, and beam shapes is as English words e, and the magnetic field that field coil produces makes electronic deflection to crucible, regulate the large I of field supply to change magnetic field intensity, reach the lip-deep position of evaporating materials (coating materials) thereby can change electron beam.Crucible is oxygen-free copper crucible.In the assembly in electron gun evaporation source, crucible is also pith.Adopt oxygen-free copper crucible, water flowing is cooling, in crucible, can place different coating materials, can change bushing position by inversion mechanism.

The negative pole of the filament parallel high pressure accelerating power source of electron gun, voltage is 15KV, and electronics accelerated motion under high voltage electric field effect forms electron beam, and line is 0.6A.

The concrete grammar that adopts vacuum vapour deposition to be coated with described silica membrane is;

1. substrate and coating materials are put into vacuum chamber, close door for vacuum chamber, be evacuated to 6 × 10 ^-3pa;

3. open filament heating power supply, heat filament;

4. the high pressure accelerating power source of unlocking electronic rifle, voltage is transferred to 15KV;

7. steam coating silicon dioxide film under the parameter of accelerating voltage 15KV, line 0.6A, deposition rate 0.35nm/s;

8. with the deposit thickness of quartz crystal vibration thickness instrument control silica membrane processed, during to 130nm, plated film finishes.

In silica deposit process, adopt ion beam assisted depositing method to improve density and the adhesive force of silica membrane, specifically:

A. in vacuum chamber, place ion source, operating current 18A, discharge power 120W, working gas is argon gas;

B. the ar-ion beam that ion beam assisted depositing ion beam energy used is 600ev first bombards 5min with described ar-ion beam to described substrate before plated film, described substrate surface is cleaned and activation;

C. in cvd silicon dioxide film, with the ar-ion beam bombardment deposition surface of 600ev;

D. with the deposit thickness of quartz crystal vibration thickness instrument control silica membrane processed, during to 120nm, plated film finishes.

In cvd silicon dioxide film, with the ar-ion beam bombardment deposition surface of 600ev, by momentum interchange and the intermixing of ion and film forming atom, thereby significantly improve density and the adhesive force of silica coating.

Spraying: spray again highly filled UV paint or PU paint on silica membrane surface; Also spray highly filled UV paint or PU paint or vacuum coating on another surface of substrate P C.

UV solidifies: if face is painted with UV paint, will solidify through UV-irradiation.

Point glue: Merlon base and protecgulum are combined closely with dotting glue method.

Milling cast gate: material handle milling unnecessary on injection molding body is removed.

Pass on and roll off the production line: product is placed on conveying belt through manipulator, be sent to test package operation.

Test package: product sticks mark through after the assay was approved, delivers to product warehouse.

After testing, the attenuation rate that prepared radar protective cover makes the millimeter wave of radar emission pass through back and forth this protective cover is below 2db.

Embodiment bis-

The radar protective cover of certain model automobile, comprises the substrate 1 with front surface and rear surface.Baseplate material is the plastic material of transparency and heat-proof shock resistance, high comprehensive performance, for example polycarbonate plate.Two of substrate surfaces are processed respectively, and the cross-section structure of this radar protective cover is shown in Fig. 1.

Substrate 1 and susceptor surface interconnect by binding agent or quadric injection mould mode after processing, and the gross thickness of substrate 1 and base 7 is 5.3mm.

Reinforced layer 2 adopts highly filled UV paint or PU paint, is sprayed on surface of the work, and THICKNESS CONTROL is at 25 microns.UV paint need solidify by UV-irradiation.

Nonferrous layer 3 is thermoprint black film or printing color rete, is decided according to the actual requirements, and thickness is 1 micron.

Nano metal layer 4 is for containing 1%(quality) indium alloy of tin, the purity of indium and tin is all 99.99%.This thicknesses of layers is 30 nanometers.Its effect is to have good metallic luster and visible reflectance, and when the millimeter wave of radar emission passes through this protective cover back and forth simultaneously, attenuation rate is very little.

Nano metal layer is very thin, and thickness is 30nm, and the microstructure of rete is taking " island " structure as main, thereby guarantee has very high resistance, very little to the radar Attenuation rate of passing through back and forth.

Protective oxide film 5 is silica membrane, and thickness is 150 nanometers, and its effect is mainly protection nano metal layer.

Coating protection layer 6 adopts highly filled UV paint or PU paint, is sprayed on surface of the work, and THICKNESS CONTROL is at 25 microns.UV paint need solidify by UV-irradiation.

Primary coat: paint and spray to surface of the work with highly filled UV.

UV solidifies: the UV paint film-forming that makes surface of the work with ultraviolet light.

Thermoprint: the region that utilizes frock to cover next procedure to want plating nano-metal layer, then scald black film or printing color rete at surface of the work.

Plating for the first time: by magnetron sputtering method or vacuum vapour deposition, be coated with nanometer indium alloy layer, strictly control its thickness and be greater than 20 megaohms/ at 30nm and sheet resistance.

Plating for the second time: by medium frequency twin-target sputtering method or electron beam vacuum vapour deposition, be coated with silica membrane, thickness is 150nm.

Embodiment tri-

The radar protective cover of certain model automobile, comprises the substrate with front surface and rear surface.Baseplate material is the plastic material of transparency and heat-proof shock resistance, high comprehensive performance, for example polycarbonate plate.Two of substrate surfaces are processed respectively, and the cross-section structure of this radar protective cover is shown in Fig. 1.

After substrate 1 and base 7 surface treatments, interconnect by binding agent or quadric injection mould mode, the gross thickness of substrate 1 and base 7 is 5mm.

Reinforced layer 2 adopts highly filled UV paint or PU paint, is sprayed on surface of the work, and THICKNESS CONTROL is at 18 microns.UV paint need solidify by UV-irradiation.

Nonferrous layer 3 is thermoprint black film or printing color rete, is decided according to the actual requirements, and thickness is 0.6 micron.

Nano metal layer 4 is for containing 3%(mass fraction) indium alloy of gallium, indium and silver-colored purity are all 99.99%.This thicknesses of layers is 50 nanometers.Its effect is to have good metallic luster and visible reflectance, and when the millimeter wave of radar emission passes through this protective cover back and forth simultaneously, attenuation rate is very little.

Nano metal layer 4 is very thin, and thickness is 50nm, and the microstructure of rete is taking " island " structure as main, thereby guarantee has very high resistance, very little to the radar Attenuation rate of passing through back and forth.

Protective oxide film 5 is silica membrane, and thickness is 120 nanometers, and its effect is mainly protection nano metal layer.

Coating protection layer 6 adopts highly filled UV paint or PU paint, is sprayed on surface of the work, and THICKNESS CONTROL is at 20 microns.UV paint need solidify by UV-irradiation.

The manufacturing process of this product mainly contain injection moulding, pre-treatment, spraying and solidify, thermoprint, magnetron sputtering or vacuum evaporation coating, medium frequency twin-target sputtering method or electron beam vacuum vapour deposition, spraying or solidify, some glue, milling cast gate, inspection, packaging etc.Process route is shown in Fig. 2.

Primary coat: paint and spray to surface of the work with highly filled UV.

Plating for the first time: by magnetron sputtering method or vacuum vapour deposition, be coated with nanometer indium alloy layer, strictly control its thickness and be greater than 20 megaohms/ at 50nm and sheet resistance.

Plating for the second time: by medium frequency twin-target sputtering method or electron beam vacuum vapour deposition, be coated with silica membrane, thickness is 120nm.

Embodiment tetra-

With embodiment mono-, the technique of different the is indium alloy of vacuum evaporation nanometer for the first time layer is to be 1 × 10 in vacuum degree ^-2under the vacuum degree of Pa, carry out continuously three phases evaporation, first stage evaporation is to evaporate 10s under 1.5 volts, and second stage evaporation is to evaporate 6s under 3.5 volts, and the phase III is to evaporate 3s under 5.5 volts, and being coated with thickness is the nano metal layer 4 of 5nm.

Vacuum vapour deposition is coated with the concrete grammar of described silica membrane and is for the second time;

1. substrate and coating materials are put into vacuum chamber, close door for vacuum chamber, be evacuated to 5 × 10 ^-3pa;

3. open filament heating power supply, heat filament;

4. the high pressure accelerating power source of unlocking electronic rifle, voltage is transferred to 6KV;

7. steam coating silicon dioxide film under the parameter of accelerating voltage 6KV, line 0.3A, deposition rate 0.3nm/s;

8. with the deposit thickness of quartz crystal vibration thickness instrument control silica membrane processed, during to 100nm, plated film finishes.

A. in vacuum chamber, place ion source, operating current 16A, discharge power 100W, working gas is argon gas;

B. the ar-ion beam that ion beam assisted depositing ion beam energy used is 400ev first bombards 1min with described ar-ion beam to described substrate before plated film, described substrate surface is cleaned and activation;

C. in cvd silicon dioxide film, with the ar-ion beam bombardment deposition surface of 400ev;

D. with the deposit thickness of quartz crystal vibration thickness instrument control silica membrane processed, during to 100nm, plated film finishes.

In cvd silicon dioxide film, with the ar-ion beam bombardment deposition surface of 400ev; By momentum interchange and the intermixing of ion and film forming atom, thereby significantly improve density and the adhesive force of silica coating.

Embodiment five

With embodiment mono-, the technique of different the is indium alloy of vacuum evaporation nanometer for the first time layer is to be 2 × 10 in vacuum degree ^-2under the vacuum degree of Pa, carry out continuously three phases evaporation, first stage evaporation is to evaporate 12s under 2.5 volts, and second stage evaporation is to evaporate 6-10s under 4.5 volts, and the phase III is to evaporate 4s under 6.5 volts.

1. substrate and coating materials are put into vacuum chamber, close door for vacuum chamber, be evacuated to 8 × 10 ^-3pa;

3. open filament heating power supply, heat filament;

4. the high pressure accelerating power source of unlocking electronic rifle, voltage is transferred to 30KV;

7. steam coating silicon dioxide film under the parameter of accelerating voltage 30KV, line 1A, deposition rate 0.4nm/s;

8. with the deposit thickness of quartz crystal vibration thickness instrument control silica membrane processed, during to 150nm, plated film finishes.

A. in vacuum chamber, place ion source, operating current 20A, discharge power 150W, working gas is argon gas;

B. the ar-ion beam that ion beam assisted depositing ion beam energy used is 800ev first bombards 3min with described ar-ion beam to described substrate before plated film, described substrate surface is cleaned and activation;

C. in cvd silicon dioxide film, with the ar-ion beam bombardment deposition surface of 800ev;

D. with the deposit thickness of quartz crystal vibration thickness instrument control silica membrane processed, during to 150nm, plated film finishes.

In cvd silicon dioxide film, with the ar-ion beam bombardment deposition surface of 800ev; By momentum interchange and the intermixing of ion and film forming atom, thereby significantly improve density and the adhesive force of silica coating.

Comparative example one

With embodiment mono-, different is that nano metal layer 4 is zinc metal level, and thickness is 80nm.After testing, the attenuation rate that prepared radar protective cover makes the millimeter wave of radar emission pass through back and forth this protective cover is more than 3%.

This specific embodiment is only explanation of the invention; it is not limitation of the present invention; those skilled in the art are reading after this specification and can make to the present embodiment the amendment that there is no creative contribution as required, but as long as within the scope of claim of the present invention, are all subject to the protection of Patent Law.

Claims

1. a preparation method for radar protective cover, is characterized in that comprising successively step:

(1) pre-treatment: substrate (1) is carried out to dedusting clean;

(2) thermoprint: the region of covering next procedure and wanting plating nano-metal layer, then in the upper thermoprint of substrate (1) or be printed with chromatograph (3);

(3) plating for the first time: adopt magnetron sputtering method or vacuum vapour deposition around described nonferrous layer (3) not the region of thermoprint or printing be coated with nanometer indium alloy layer, the nano metal layer (5) that to form thickness be 5-50nm;

(4) spraying and curing: form coating protection layer (6) after the upper spray of described nano metal layer (4) UV paints or PU paint, be curing;

(5) face is coated with or Vacuum Deposition: above spray UV paint or PU paint or vacuum coating on another surface of described substrate (1) and form reinforced layer (2).

2. the preparation method of a kind of radar protective cover according to claim 1, is characterized in that: described step (1) pre-treatment specifically, first by first gained injection molding body electrostatic precipitation, is then used hairbrush dedusting, finally adopts Dry ice cleaning.

3. the preparation method of a kind of radar protective cover according to claim 2; it is characterized in that: the region that described step (2) is covered next procedure and wanted plating nano-metal layer, is then formed with chromatograph (3) at black film or the colored film layer of the upper thermoprint of substrate (1) or printing 0.1-1 micron thickness.

4. the preparation method of a kind of radar protective cover according to claim 3, is characterized in that: the metal ingredient of described step (3) nano metal layer (4) is indium and accounts for one or more of tin that mass percent is 0-10%, gallium, silver, germanium.

5. the preparation method of a kind of radar protective cover according to claim 4, is characterized in that: described step (3) adopt magnetron sputtering method or vacuum vapour deposition described nonferrous layer (3) upper form island structure, thickness is the nanometer indium alloy layer that 5-50nm and sheet resistance are greater than 20 megaohms/.

6. the preparation method of a kind of radar protective cover according to claim 5, is characterized in that: the metal ingredient of described step (3) nano metal layer (4) is the indium alloy containing 5% quality silver.

7. the preparation method of a kind of radar protective cover according to claim 6, is characterized in that: the technique that adopts vacuum vapour deposition to be coated with described nano metal layer (4) is to be (1-2) × 10 in vacuum degree ^-2under the vacuum degree of Pa, carry out continuously three phases evaporation, first stage evaporation is to evaporate 10-12s under 1.5-2.5 volt, and second stage evaporation is to evaporate 6-10s under 3.5-4.5 volt, and the phase III is to evaporate 3-4s under 5.5-6.5 volt.

8. according to the preparation method of a kind of radar protective cover described in claim 1-7 any one; it is characterized in that: described in described preparation method is also included in, after plating, plate for the second time for the first time: adopt intermediate frequency twin-target sputtering method or electron beam vacuum vapour deposition on described nano metal layer (4), to be coated with the oxide film that thickness is 100-150nm, form protective oxide film (5).

9. the preparation method of a kind of radar protective cover according to claim 8, is characterized in that: described oxide film is silica membrane.

10. the preparation method of a kind of radar protective cover according to claim 9, it is characterized in that: adopt electron beam vacuum vapour deposition to be coated with in the equipment of described silica membrane, main element is the evaporation source that comprises electron gun, field coil and crucible, and described electron gun comprises the anode of the filament of electron emission, the focusing electrode that converges electronics and acceleration electronics; Described field coil and accelerating field are perpendicular.

The preparation method of 11. a kind of radar protective covers according to claim 10; it is characterized in that: the negative pole of the filament parallel high pressure accelerating power source of described electron gun; voltage is 6-30KV, and electronics accelerated motion under high voltage electric field effect forms electron beam, and line is 0.3-1A.

The preparation method of 12. a kind of radar protective covers according to claim 11, is characterized in that: described crucible is oxygen-free copper crucible.

13. want the preparation method of a kind of radar protective cover described in 9-12 any one according to right, it is characterized in that: the method that adopts vacuum vapour deposition to be coated with described silica membrane is:

3. open filament heating power supply, heat filament;

The preparation method of 14. a kind of radar protective covers according to claim 13, is characterized in that: in silica deposit process, adopt ion beam assisted depositing method to improve density and the adhesive force of silica membrane, specifically:

The preparation method of 15. a kind of radar protective covers according to claim 8, is characterized in that: described step (4) forms coating protection layer (6) at UV paint or the PU paint of the upper spraying of described protective oxide film (5) 10-25 micron thickness.

The preparation method of 16. a kind of radar protective covers according to claim 8, is characterized in that: described step (5) above sprays the UV paint of 10-25 micron thickness on another surface of described substrate (1) or PU paints or vacuum coating forms reinforced layer (2).

17. according to the preparation method of a kind of radar protective cover described in claim 1-7 any one, it is characterized in that: described preparation method toasts before being also included in pre-treatment step.

18. according to the preparation method of a kind of radar protective cover described in claim 1-7 any one; it is characterized in that: described radar protective cover also comprises the base (7) that is arranged on described substrate (1) rear; described substrate (1) and described base (7) are polycarbonate plate, and described substrate (1) and described base (7) are combined closely by dotting glue method.