CN106287413A - A kind of for illuminating lamp under water - Google Patents

Abstract

The application relates to a kind of for illuminating lamp under water, including lamp housing, lampshade and luminescence component, described lamp housing is cylindric, described luminescence component is arranged on lamp housing one end, described lampshade is on described luminescence component, and described lamp housing top and bottom are furnished with top cover and bottom, described top cover and bottom and are connected with the locking of described lamp housing by lock-screw.

Description

A kind of for illuminating lamp under water

Technical field

The application relates to illuminating lamp field, particularly relates to a kind of for illuminating lamp under water.

Background technology

Underwater luminaire is called for short underwater lamp, it is simply that being contained in the lamp under the bottom, its outward appearance is typically small, and external form is buried with some Lamp is similar, generally LED light source, has the features such as energy-saving and environmental protection, life-span length, volume are little.The when of energising, can send Multiple color, bright and colourful, usually it is contained in park or pool with fountain, there is the strongest sight.

But, owing to illuminating lamp works the most under water, its internal medium humidity is relatively big, when running into the feelings that the temperature difference is bigger During condition, its cover surface is easily atomized, and makes troubles to illumination work.

Summary of the invention

It is desirable to provide it is a kind of for illuminating lamp under water, to solve problem set forth above.

Embodiments of the invention provide a kind of for illuminating lamp under water, including lamp housing, lampshade and luminescence component, institute It is cylindric for stating lamp housing, and described luminescence component is arranged on lamp housing one end, described lampshade on described luminescence component, described lamp housing Top and bottom are furnished with top cover and bottom, described top cover and bottom and are connected with the locking of described lamp housing by lock-screw, described lamp Cover is antifog glass substrate.

The technical scheme that embodiments of the invention provide can include following beneficial effect:

The lampshade of the underwater luminaire of the present invention is antifog glass substrate, and this antifog glass substrate surface is provided with antifog painting Layer, it is less than 1 degree to the contact angle of water droplet, has preferable hydrophilic effect, it is possible to prevent glass substrate surface from water smoke etc. occur, Thus solve problem set forth above.

Aspect and advantage that the application adds will part be given in the following description, and part will become from the following description Obtain substantially, or recognized by the practice of the application.It should be appreciated that above general description and details hereinafter only describe It is exemplary and explanatory, the application can not be limited.

Accompanying drawing explanation

The invention will be further described to utilize accompanying drawing, but the embodiment in accompanying drawing does not constitute any limit to the present invention System, for those of ordinary skill in the art, on the premise of not paying creative work, it is also possible to obtain according to the following drawings Other accompanying drawing.

Fig. 1 is the structural representation of underwater luminaire of the present invention.

Fig. 2 is the Making programme figure of antifogging coating of the present invention.

Detailed description of the invention

Here will illustrate exemplary embodiment in detail, its example represents in the accompanying drawings.Explained below relates to During accompanying drawing, unless otherwise indicated, the same numbers in different accompanying drawings represents same or analogous key element.Following exemplary embodiment Described in embodiment do not represent all embodiments consistent with the present invention.On the contrary, they are only with the most appended The example of the apparatus and method that some aspects that described in detail in claims, the present invention are consistent.

Transparent material has a wide range of applications in industrial and agricultural production and life, but, due to the impact of surrounding, special Not being the impact of humidity in environment, transparent material surface easily produces atomization, causes transparency to decline, to production and the life of people Live and bring inconvenience, even cause heavy losses.

Anti-fogging measure is mainly started with from the condition destroying fogging, and one is from thermodynamics, installs heater and makes base material Surface temperature is higher than steam dew point, or the little dewdrop that installation ultrasound wave dispersion makes steam produce volatilized within the extremely short time For steam, the measure being usually taken is the method heated with hair dryer or film metal silk, removes transparent material surface Water smoke；Two is from the performance changing material surface, changes chemical composition or the microstructure of substrate surface, such as at not shadow In the case of ringing the function of material own, construct one layer of hydrophilic or hydrophobic wear-resistant coating at material surface, when little water drop contact During to this coating, due to the hydrophilic of coating or hydrophobic effect, little water droplet can coating surface sprawl into thin layer moisture film or Person tumbles, thus inhibits the formation of coating surface water smoke.

But, in prior art, using hair dryer or tinsel heating, there is device complicated, original paper is many, cost Height, the problem such as fragile, therefore coating is the main method solving transparent material surface fogging.

Application scenarios one:

It is a kind of for illuminating lamp under water that Fig. 1 shows that embodiments herein relates to, including lamp housing 1, and lampshade 2 and sending out Optical assembly 3, it is characterised in that described lamp housing 1 is cylindric, described luminescence component 3 is arranged on lamp housing 1 one end, and described lampshade 2 covers On described luminescence component 3, described lamp housing 1 top and bottom are furnished with top cover 4 and bottom 5, described top cover 4 and bottom 5 by lock Tight screw is connected with the locking of described lamp housing 1, is provided with seal washer, described sealing gasket between described lamp housing 1 and top cover 4 and bottom 5 Circle is waterproof elastic packing packing ring, and with sealant sealing, described lampshade 2 is antifog glass substrate.

The lampshade of the underwater luminaire of the present invention is antifog glass substrate, and this antifog glass substrate surface is provided with antifog painting Layer, has preferable hydrophilic effect, it is possible to prevent glass substrate surface from water smoke etc. occur.

Preferably, described antifog glass substrate is high temp glass substrate, and described high temp glass substrate surface is for passing through electrostatic The antifogging coating of self-assembling method deposition, described high temp glass substrate is through polyelectrolyte surface modification treatment；This high temp glass Antifogging coating with positive charge, can be deposited on table by electrostatic attraction through polyelectrolyte process rear surface by substrate surface Face.

Preferably, described antifogging coating is CaCO₃/SiO₂Compound particle, described CaCO₃/SiO₂Compound particle is nucleocapsid knot Structure, CaCO₃Particle is core, SiO₂Nanoparticle adsorbs at described CaCO₃Particle surface forms shell structure, described CaCO₃Particle Footpath is 1～10 μm, described SiO₂Nano particle diameter is 50～100nm.

Due to CaCO₃At high temperature produce after calcining and decompose, have CO₂Gas produces, CO₂Gas breaks through SiO₂Nanoparticle The shell structure formed so that this shell structure surface forms aperture, is formed by SiO₂The hollow ball composition that nanoparticle is constituted is many Hole coating, and increase the surface area of shell wall, adsorbed water molecule on the most more hollow ball wall, on the other hand, hollow ball Duct on wall, due to capillary effect, also can provide sprawling of passage, beneficially water droplet in entering ball for hydrone, increase figure The hydrophilic of layer；3rd, hollow ball also can increase light transmittance, it is to avoid because the effect of coating causes the decline of light transmittance.

Preferably, described CaCO₃Particle surface coating layer of polyethylene ketopyrrolidine.

This polyvinylpyrrolidone is water-soluble high-molecular compound, can be at CaCO₃Particle is protected as one layer of colloid Material, it is to avoid without CaCO during high-temperature calcination₃Particle decomposes in advance.

Preferably, deposition has the high temp glass substrate of described antifogging coating and the contact angle of water droplet less than 1 degree, possesses higher Hydrophilic and self-cleaning property.

Further preferred, by Fig. 2, the making step of described antifogging coating is as follows:

Step one, prepares CaCO₃Particle:

Choose CaCO₃Particle, by its ultrasonic cleaning, then takes 3g polyvinylpyrrolidone and joins 100ml deionized water In, the CaCO after cleaning₃Particle adds in deionized water, and the most ultrasonic 30min makes CaCO₃Particle surface coats a strata second Alkene pyrrolidone；

Step 2, prepares SiO₂Nanoparticle:

By 5ml ammonia, 100ml dehydrated alcohol joins stirring at normal temperature 10min in conical flask, stirs 2min at 60 DEG C, The lower dropping 3ml tetraethyl orthosilicate of stirring, continues stirring 12h at 60 DEG C, and obtaining translucent is the solid of 50nm containing particle diameter SiO₂The suspension of nanoparticle；

Step 3, prepares CaCO₃/SiO₂Composite nanoparticle:

A) by the CaCO of step steady₃Particle ultrasonic disperse forms suspension in water, by isopyknic concentration be 1～ The PDDA of 3mg/ml joins in this suspension, magnetic agitation, makes PDDA pass through Coulomb force absorption and is assembled in CaCO₃Particle table Face, centrifugation, supersound washing, remove the PDDA of physical absorption, then the CaCO obtained₃Particle is dispersed in water and obtains all Even scattered suspension；

B) suspension obtained above is joined in PSS aqueous solution, magnetic agitation 3h, centrifugation, supersound washing, To CaCO₃Surface adsorption has the spheroidal particle of polyvinylpyrrolidone, PDDA and PSS, repeat the above steps so that CaCO₃Particle Surface adsorption is uniform；

C) by CaCO obtained above₃Particle joins prepared SiO₂In the suspension of nanoparticle, magnetic agitation 6 ～10h, centrifugation, supersound washing removes unadsorbed SiO₂Nanoparticle, repeat the above steps so that SiO₂Nanoparticle At CaCO₃Particle surface absorption uniformly, adsorbs twice PDDA/SiO the most again₂Nanoparticle, obtains CaCO₃/SiO₂Compound grain Son, and SiO₂Nanoparticle is three layers；

Step 4, prepares antifogging coating:

A) Substrate treatment, using volume ratio is the 98%H of 7:3₂SO₄And 30%H₂O₂To high temp glass substrate immersion treatment, The high temp glass substrate distilled water wash that will process, then dry up with nitrogen；

B) the high temp glass substrate after cleaning alternately is immersed in PDDA and PSS solution, and distilled water wash thing is used in centre PDDA and PSS of reason absorption, covers until obtaining obtaining 7 layers of PDDA and 6 layers of PSS at high temp glass substrate surface；

C) high temp glass substrate obtained above is immersed in the CaCO that step 3 obtains₃/SiO₂Compound particle suspension In, stand 5h, deposit one layer of CaCO at high temp glass substrate surface₃/SiO₂Compound particle coating, then by this high temp glass base Sheet is put in Muffle furnace, sinters 10h so that CaCO at 600～850 DEG C₃/SiO₂CaCO in compound particle₃Pyrolytic, The SiO of coarse structure and pore structure is had to deposition₂The high temp glass substrate of hollow ball coating.

Application scenarios two:

It is a kind of for illuminating lamp under water that Fig. 1 shows that embodiments herein relates to, including lamp housing 1, and lampshade 2 and sending out Optical assembly 3, it is characterised in that described lamp housing 1 is cylindric, described luminescence component 3 is arranged on lamp housing 1 one end, and described lampshade 2 covers On described luminescence component 3, described lamp housing 1 top and bottom are furnished with top cover 4 and bottom 5, described top cover 4 and bottom 5 by lock Tight screw is connected with the locking of described lamp housing 1, is provided with seal washer, described sealing gasket between described lamp housing 1 and top cover 4 and bottom 5 Circle is waterproof elastic packing packing ring, and with sealant sealing, described lampshade 2 is antifog glass substrate.

The lampshade of the underwater luminaire of the present invention is antifog glass substrate, and this antifog glass substrate surface is provided with antifog painting Layer, has preferable hydrophilic effect, it is possible to prevent glass substrate surface from water smoke etc. occur.

Preferably, described antifog glass substrate is high temp glass substrate, and described high temp glass substrate surface is for passing through electrostatic The antifogging coating of self-assembling method deposition, described high temp glass substrate is through polyelectrolyte surface modification treatment；This high temp glass Antifogging coating with positive charge, can be deposited on table by electrostatic attraction through polyelectrolyte process rear surface by substrate surface Face.

Preferably, described antifogging coating is CaCO₃/SiO₂Compound particle, described CaCO₃/SiO₂Compound particle is nucleocapsid knot Structure, CaCO₃Particle is core, SiO₂Nanoparticle adsorbs at described CaCO₃Particle surface forms shell structure, described CaCO₃Particle Footpath is 1 μm, described SiO₂Nano particle diameter is 10nm.

Due to CaCO₃At high temperature produce after calcining and decompose, have CO₂Gas produces, CO₂Gas breaks through SiO₂Nanoparticle The shell structure formed so that this shell structure surface forms aperture, is formed by SiO₂The hollow ball composition that nanoparticle is constituted is many Hole coating, and increase the surface area of shell wall, adsorbed water molecule on the most more hollow ball wall, on the other hand, hollow ball Duct on wall, due to capillary effect, also can provide sprawling of passage, beneficially water droplet in entering ball for hydrone, increase figure The hydrophilic of layer；3rd, hollow ball also can increase light transmittance, it is to avoid because the effect of coating causes the decline of light transmittance.

Preferably, described CaCO₃Particle surface coating layer of polyethylene ketopyrrolidine.

This polyvinylpyrrolidone is water-soluble high-molecular compound, can be at CaCO₃Particle is protected as one layer of colloid Material, it is to avoid without CaCO during high-temperature calcination₃Particle decomposes in advance.

Preferably, deposition has the high temp glass substrate of described antifogging coating and the contact angle of water droplet less than 1 degree, possesses higher Hydrophilic and self-cleaning property.

Further preferred, by Fig. 2, the making step of described antifogging coating is as follows:

Step one, prepares CaCO₃Particle:

Choose CaCO₃Particle, by its ultrasonic cleaning, then takes 3g polyvinylpyrrolidone and joins 100ml deionized water In, the CaCO after cleaning₃Particle adds in deionized water, and the most ultrasonic 30min makes CaCO₃Particle surface coats a strata second Alkene pyrrolidone；

Step 2, prepares SiO₂Nanoparticle:

By 5ml ammonia, 100ml dehydrated alcohol joins stirring at normal temperature 10min in conical flask, stirs 2min at 60 DEG C, The lower dropping 3ml tetraethyl orthosilicate of stirring, continues stirring 12h at 60 DEG C, and obtaining translucent is the solid of 50nm containing particle diameter SiO₂The suspension of nanoparticle；

Step 3, prepares CaCO₃/SiO₂Composite nanoparticle:

A) by the CaCO of step steady₃Particle ultrasonic disperse forms suspension in water, by isopyknic concentration be 1～ The PDDA of 3mg/ml joins in this suspension, magnetic agitation, makes PDDA pass through Coulomb force absorption and is assembled in CaCO₃Particle table Face, centrifugation, supersound washing, remove the PDDA of physical absorption, then the CaCO obtained₃Particle is dispersed in water and obtains all Even scattered suspension；

B) suspension obtained above is joined in PSS aqueous solution, magnetic agitation 3h, centrifugation, supersound washing, To CaCO₃Surface adsorption has the spheroidal particle of polyvinylpyrrolidone, PDDA and PSS, repeat the above steps so that CaCO₃Particle Surface adsorption is uniform；

C) by CaCO obtained above₃Particle joins prepared SiO₂In the suspension of nanoparticle, magnetic agitation 6 ～10h, centrifugation, supersound washing removes unadsorbed SiO₂Nanoparticle, repeat the above steps so that SiO₂Nanoparticle At CaCO₃Particle surface absorption uniformly, adsorbs twice PDDA/SiO the most again₂Nanoparticle, obtains CaCO₃/SiO₂Compound grain Son, and SiO₂Nanoparticle is three layers；

Step 4, prepares antifogging coating:

A) Substrate treatment, using volume ratio is the 98%H of 7:3₂SO₄And 30%H₂O₂To high temp glass substrate immersion treatment, The high temp glass substrate distilled water wash that will process, then dry up with nitrogen；

B) the high temp glass substrate after cleaning alternately is immersed in PDDA and PSS solution, and distilled water wash thing is used in centre PDDA and PSS of reason absorption, covers until obtaining obtaining 7 layers of PDDA and 6 layers of PSS at high temp glass substrate surface；

C) high temp glass substrate obtained above is immersed in the CaCO that step 3 obtains₃/SiO₂Compound particle suspension In, stand 5h, deposit one layer of CaCO at high temp glass substrate surface₃/SiO₂Compound particle coating, then by this high temp glass base Sheet is put in Muffle furnace, sinters 10h so that CaCO at 600～850 DEG C₃/SiO₂CaCO in compound particle₃Pyrolytic, The SiO of coarse structure and pore structure is had to deposition₂The high temp glass substrate of hollow ball coating.

Application scenarios three:

It is a kind of for illuminating lamp under water that Fig. 1 shows that embodiments herein relates to, including lamp housing 1, and lampshade 2 and sending out Optical assembly 3, it is characterised in that described lamp housing 1 is cylindric, described luminescence component 3 is arranged on lamp housing 1 one end, and described lampshade 2 covers On described luminescence component 3, described lamp housing 1 top and bottom are furnished with top cover 4 and bottom 5, described top cover 4 and bottom 5 by lock Tight screw is connected with the locking of described lamp housing 1, is provided with seal washer, described sealing gasket between described lamp housing 1 and top cover 4 and bottom 5 Circle is waterproof elastic packing packing ring, and with sealant sealing, described lampshade 2 is antifog glass substrate.

The lampshade of the underwater luminaire of the present invention is antifog glass substrate, and this antifog glass substrate surface is provided with antifog painting Layer, has preferable hydrophilic effect, it is possible to prevent glass substrate surface from water smoke etc. occur.

Preferably, described antifog glass substrate is high temp glass substrate, and described high temp glass substrate surface is for passing through electrostatic The antifogging coating of self-assembling method deposition, described high temp glass substrate is through polyelectrolyte surface modification treatment；This high temp glass Antifogging coating with positive charge, can be deposited on table by electrostatic attraction through polyelectrolyte process rear surface by substrate surface Face.

Preferably, described antifogging coating is CaCO₃/SiO₂Compound particle, described CaCO₃/SiO₂Compound particle is nucleocapsid knot Structure, CaCO₃Particle is core, SiO₂Nanoparticle adsorbs at described CaCO₃Particle surface forms shell structure, described CaCO₃Particle Footpath is 3 μm, described SiO₂Nano particle diameter is 30nm.

Due to CaCO₃At high temperature produce after calcining and decompose, have CO₂Gas produces, CO₂Gas breaks through SiO₂Nanoparticle The shell structure formed so that this shell structure surface forms aperture, is formed by SiO₂The hollow ball composition that nanoparticle is constituted is many Hole coating, and increase the surface area of shell wall, adsorbed water molecule on the most more hollow ball wall, on the other hand, hollow ball Duct on wall, due to capillary effect, also can provide sprawling of passage, beneficially water droplet in entering ball for hydrone, increase figure The hydrophilic of layer；3rd, hollow ball also can increase light transmittance, it is to avoid because the effect of coating causes the decline of light transmittance.

Preferably, described CaCO₃Particle surface coating layer of polyethylene ketopyrrolidine.

This polyvinylpyrrolidone is water-soluble high-molecular compound, can be at CaCO₃Particle is protected as one layer of colloid Material, it is to avoid without CaCO during high-temperature calcination₃Particle decomposes in advance.

Preferably, deposition has the high temp glass substrate of described antifogging coating and the contact angle of water droplet less than 2 degree, possesses higher Hydrophilic and self-cleaning property.

Further preferred, by Fig. 2, the making step of described antifogging coating is as follows:

Step one, prepares CaCO₃Particle:

Choose CaCO₃Particle, by its ultrasonic cleaning, then takes 3g polyvinylpyrrolidone and joins 100ml deionized water In, the CaCO after cleaning₃Particle adds in deionized water, and the most ultrasonic 30min makes CaCO₃Particle surface coats a strata second Alkene pyrrolidone；

Step 2, prepares SiO₂Nanoparticle:

By 5ml ammonia, 100ml dehydrated alcohol joins stirring at normal temperature 10min in conical flask, stirs 2min at 60 DEG C, The lower dropping 3ml tetraethyl orthosilicate of stirring, continues stirring 12h at 60 DEG C, and obtaining translucent is the solid of 50nm containing particle diameter SiO₂The suspension of nanoparticle；

Step 3, prepares CaCO₃/SiO₂Composite nanoparticle:

A) by the CaCO of step steady₃Particle ultrasonic disperse forms suspension in water, by isopyknic concentration be 1～ The PDDA of 3mg/ml joins in this suspension, magnetic agitation, makes PDDA pass through Coulomb force absorption and is assembled in CaCO₃Particle table Face, centrifugation, supersound washing, remove the PDDA of physical absorption, then the CaCO obtained₃Particle is dispersed in water and obtains all Even scattered suspension；

B) suspension obtained above is joined in PSS aqueous solution, magnetic agitation 3h, centrifugation, supersound washing, To CaCO₃Surface adsorption has the spheroidal particle of polyvinylpyrrolidone, PDDA and PSS, repeat the above steps so that CaCO₃Particle Surface adsorption is uniform；

C) by CaCO obtained above₃Particle joins prepared SiO₂In the suspension of nanoparticle, magnetic agitation 6 ～10h, centrifugation, supersound washing removes unadsorbed SiO₂Nanoparticle, repeat the above steps so that SiO₂Nanoparticle At CaCO₃Particle surface absorption uniformly, adsorbs twice PDDA/SiO the most again₂Nanoparticle, obtains CaCO₃/SiO₂Compound grain Son, and SiO₂Nanoparticle is three layers；

Step 4, prepares antifogging coating:

A) Substrate treatment, using volume ratio is the 98%H of 7:3₂SO₄And 30%H₂O₂To high temp glass substrate immersion treatment, The high temp glass substrate distilled water wash that will process, then dry up with nitrogen；

B) the high temp glass substrate after cleaning alternately is immersed in PDDA and PSS solution, and distilled water wash thing is used in centre PDDA and PSS of reason absorption, covers until obtaining obtaining 7 layers of PDDA and 6 layers of PSS at high temp glass substrate surface；

C) high temp glass substrate obtained above is immersed in the CaCO that step 3 obtains₃/SiO₂Compound particle suspension In, stand 5h, deposit one layer of CaCO at high temp glass substrate surface₃/SiO₂Compound particle coating, then by this high temp glass base Sheet is put in Muffle furnace, sinters 10h so that CaCO at 600～850 DEG C₃/SiO₂CaCO in compound particle₃Pyrolytic, The SiO of coarse structure and pore structure is had to deposition₂The high temp glass substrate of hollow ball coating.

Application scenarios four:

It is a kind of for illuminating lamp under water that Fig. 1 shows that embodiments herein relates to, including lamp housing 1, and lampshade 2 and sending out Optical assembly 3, it is characterised in that described lamp housing 1 is cylindric, described luminescence component 3 is arranged on lamp housing 1 one end, and described lampshade 2 covers On described luminescence component 3, described lamp housing 1 top and bottom are furnished with top cover 4 and bottom 5, described top cover 4 and bottom 5 by lock Tight screw is connected with the locking of described lamp housing 1, is provided with seal washer, described sealing gasket between described lamp housing 1 and top cover 4 and bottom 5 Circle is waterproof elastic packing packing ring, and with sealant sealing, described lampshade 2 is antifog glass substrate.

The lampshade of the underwater luminaire of the present invention is antifog glass substrate, and this antifog glass substrate surface is provided with antifog painting Layer, has preferable hydrophilic effect, it is possible to prevent glass substrate surface from water smoke etc. occur.

Preferably, described antifog glass substrate is high temp glass substrate, and described high temp glass substrate surface is for passing through electrostatic The antifogging coating of self-assembling method deposition, described high temp glass substrate is through polyelectrolyte surface modification treatment；This high temp glass Antifogging coating with positive charge, can be deposited on table by electrostatic attraction through polyelectrolyte process rear surface by substrate surface Face.

Preferably, described antifogging coating is CaCO₃/SiO₂Compound particle, described CaCO₃/SiO₂Compound particle is nucleocapsid knot Structure, CaCO₃Particle is core, SiO₂Nanoparticle adsorbs at described CaCO₃Particle surface forms shell structure, described CaCO₃Particle Footpath is 6 μm, described SiO₂Nano particle diameter is 60nm.

Due to CaCO₃At high temperature produce after calcining and decompose, have CO₂Gas produces, CO₂Gas breaks through SiO₂Nanoparticle The shell structure formed so that this shell structure surface forms aperture, is formed by SiO₂The hollow ball composition that nanoparticle is constituted is many Hole coating, and increase the surface area of shell wall, adsorbed water molecule on the most more hollow ball wall, on the other hand, hollow ball Duct on wall, due to capillary effect, also can provide sprawling of passage, beneficially water droplet in entering ball for hydrone, increase figure The hydrophilic of layer；3rd, hollow ball also can increase light transmittance, it is to avoid because the effect of coating causes the decline of light transmittance.

Preferably, described CaCO₃Particle surface coating layer of polyethylene ketopyrrolidine.

This polyvinylpyrrolidone is water-soluble high-molecular compound, can be at CaCO₃Particle is protected as one layer of colloid Material, it is to avoid without CaCO during high-temperature calcination₃Particle decomposes in advance.

Preferably, deposition has the high temp glass substrate of described antifogging coating and the contact angle of water droplet less than 3 degree, possesses higher Hydrophilic and self-cleaning property.

Further preferred, by Fig. 2, the making step of described antifogging coating is as follows:

Step one, prepares CaCO₃Particle:

Choose CaCO₃Particle, by its ultrasonic cleaning, then takes 3g polyvinylpyrrolidone and joins 100ml deionized water In, the CaCO after cleaning₃Particle adds in deionized water, and the most ultrasonic 30min makes CaCO₃Particle surface coats a strata second Alkene pyrrolidone；

Step 2, prepares SiO₂Nanoparticle:

By 5ml ammonia, 100ml dehydrated alcohol joins stirring at normal temperature 10min in conical flask, stirs 2min at 60 DEG C, The lower dropping 3ml tetraethyl orthosilicate of stirring, continues stirring 12h at 60 DEG C, and obtaining translucent is the solid of 50nm containing particle diameter SiO₂The suspension of nanoparticle；

Step 3, prepares CaCO₃/SiO₂Composite nanoparticle:

A) by the CaCO of step steady₃Particle ultrasonic disperse forms suspension in water, by isopyknic concentration be 1～ The PDDA of 3mg/ml joins in this suspension, magnetic agitation, makes PDDA pass through Coulomb force absorption and is assembled in CaCO₃Particle table Face, centrifugation, supersound washing, remove the PDDA of physical absorption, then the CaCO obtained₃Particle is dispersed in water and obtains all Even scattered suspension；

B) suspension obtained above is joined in PSS aqueous solution, magnetic agitation 3h, centrifugation, supersound washing, To CaCO₃Surface adsorption has the spheroidal particle of polyvinylpyrrolidone, PDDA and PSS, repeat the above steps so that CaCO₃Particle Surface adsorption is uniform；

C) by CaCO obtained above₃Particle joins prepared SiO₂In the suspension of nanoparticle, magnetic agitation 6 ～10h, centrifugation, supersound washing removes unadsorbed SiO₂Nanoparticle, repeat the above steps so that SiO₂Nanoparticle At CaCO₃Particle surface absorption uniformly, adsorbs twice PDDA/SiO the most again₂Nanoparticle, obtains CaCO₃/SiO₂Compound grain Son, and SiO₂Nanoparticle is three layers；

Step 4, prepares antifogging coating:

A) Substrate treatment, using volume ratio is the 98%H of 7:3₂SO₄And 30%H₂O₂To high temp glass substrate immersion treatment, The high temp glass substrate distilled water wash that will process, then dry up with nitrogen；

B) the high temp glass substrate after cleaning alternately is immersed in PDDA and PSS solution, and distilled water wash thing is used in centre PDDA and PSS of reason absorption, covers until obtaining obtaining 7 layers of PDDA and 6 layers of PSS at high temp glass substrate surface；

C) high temp glass substrate obtained above is immersed in the CaCO that step 3 obtains₃/SiO₂Compound particle suspension In, stand 5h, deposit one layer of CaCO at high temp glass substrate surface₃/SiO₂Compound particle coating, then by this high temp glass base Sheet is put in Muffle furnace, sinters 10h so that CaCO at 600～850 DEG C₃/SiO₂CaCO in compound particle₃Pyrolytic, The SiO of coarse structure and pore structure is had to deposition₂The high temp glass substrate of hollow ball coating.

Application scenarios five:

It is a kind of for illuminating lamp under water that Fig. 1 shows that embodiments herein relates to, including lamp housing 1, and lampshade 2 and sending out Optical assembly 3, it is characterised in that described lamp housing 1 is cylindric, described luminescence component 3 is arranged on lamp housing 1 one end, and described lampshade 2 covers On described luminescence component 3, described lamp housing 1 top and bottom are furnished with top cover 4 and bottom 5, described top cover 4 and bottom 5 by lock Tight screw is connected with the locking of described lamp housing 1, is provided with seal washer, described sealing gasket between described lamp housing 1 and top cover 4 and bottom 5 Circle is waterproof elastic packing packing ring, and with sealant sealing, described lampshade 2 is antifog glass substrate.

The lampshade of the underwater luminaire of the present invention is antifog glass substrate, and this antifog glass substrate surface is provided with antifog painting Layer, has preferable hydrophilic effect, it is possible to prevent glass substrate surface from water smoke etc. occur.

Preferably, described antifog glass substrate is high temp glass substrate, and described high temp glass substrate surface is for passing through electrostatic The antifogging coating of self-assembling method deposition, described high temp glass substrate is through polyelectrolyte surface modification treatment；This high temp glass Antifogging coating with positive charge, can be deposited on table by electrostatic attraction through polyelectrolyte process rear surface by substrate surface Face.

Preferably, described antifogging coating is CaCO₃/SiO₂Compound particle, described CaCO₃/SiO₂Compound particle is nucleocapsid knot Structure, CaCO₃Particle is core, SiO₂Nanoparticle adsorbs at described CaCO₃Particle surface forms shell structure, described CaCO₃Particle Footpath is 10 μm, described SiO₂Nano particle diameter is 100nm.

Due to CaCO₃At high temperature produce after calcining and decompose, have CO₂Gas produces, CO₂Gas breaks through SiO₂Nanoparticle The shell structure formed so that this shell structure surface forms aperture, is formed by SiO₂The hollow ball composition that nanoparticle is constituted is many Hole coating, and increase the surface area of shell wall, adsorbed water molecule on the most more hollow ball wall, on the other hand, hollow ball Duct on wall, due to capillary effect, also can provide sprawling of passage, beneficially water droplet in entering ball for hydrone, increase figure The hydrophilic of layer；3rd, hollow ball also can increase light transmittance, it is to avoid because the effect of coating causes the decline of light transmittance.

Preferably, described CaCO₃Particle surface coating layer of polyethylene ketopyrrolidine.

This polyvinylpyrrolidone is water-soluble high-molecular compound, can be at CaCO₃Particle is protected as one layer of colloid Material, it is to avoid without CaCO during high-temperature calcination₃Particle decomposes in advance.

Preferably, deposition has the high temp glass substrate of described antifogging coating and the contact angle of water droplet less than 3 degree, possesses higher Hydrophilic and self-cleaning property.

Further preferred, by Fig. 2, the making step of described antifogging coating is as follows:

Step one, prepares CaCO₃Particle:

Choose CaCO₃Particle, by its ultrasonic cleaning, then takes 3g polyvinylpyrrolidone and joins 100ml deionized water In, the CaCO after cleaning₃Particle adds in deionized water, and the most ultrasonic 30min makes CaCO₃Particle surface coats a strata second Alkene pyrrolidone；

Step 2, prepares SiO₂Nanoparticle:

By 5ml ammonia, 100ml dehydrated alcohol joins stirring at normal temperature 10min in conical flask, stirs 2min at 60 DEG C, The lower dropping 3ml tetraethyl orthosilicate of stirring, continues stirring 12h at 60 DEG C, and obtaining translucent is the solid of 50nm containing particle diameter SiO₂The suspension of nanoparticle；

Step 3, prepares CaCO₃/SiO₂Composite nanoparticle:

A) by the CaCO of step steady₃Particle ultrasonic disperse forms suspension in water, by isopyknic concentration be 1～ The PDDA of 3mg/ml joins in this suspension, magnetic agitation, makes PDDA pass through Coulomb force absorption and is assembled in CaCO₃Particle table Face, centrifugation, supersound washing, remove the PDDA of physical absorption, then the CaCO obtained₃Particle is dispersed in water and obtains all Even scattered suspension；

B) suspension obtained above is joined in PSS aqueous solution, magnetic agitation 3h, centrifugation, supersound washing, To CaCO₃Surface adsorption has the spheroidal particle of polyvinylpyrrolidone, PDDA and PSS, repeat the above steps so that CaCO₃Particle Surface adsorption is uniform；

C) by CaCO obtained above₃Particle joins prepared SiO₂In the suspension of nanoparticle, magnetic agitation 6 ～10h, centrifugation, supersound washing removes unadsorbed SiO₂Nanoparticle, repeat the above steps so that SiO₂Nanoparticle At CaCO₃Particle surface absorption uniformly, adsorbs twice PDDA/SiO the most again₂Nanoparticle, obtains CaCO₃/SiO₂Compound grain Son, and SiO₂Nanoparticle is three layers；

Step 4, prepares antifogging coating:

A) Substrate treatment, using volume ratio is the 98%H of 7:3₂SO₄And 30%H₂O₂To high temp glass substrate immersion treatment, The high temp glass substrate distilled water wash that will process, then dry up with nitrogen；

B) the high temp glass substrate after cleaning alternately is immersed in PDDA and PSS solution, and distilled water wash thing is used in centre PDDA and PSS of reason absorption, covers until obtaining obtaining 7 layers of PDDA and 6 layers of PSS at high temp glass substrate surface；

C) high temp glass substrate obtained above is immersed in the CaCO that step 3 obtains₃/SiO₂Compound particle suspension In, stand 5h, deposit one layer of CaCO at high temp glass substrate surface₃/SiO₂Compound particle coating, then by this high temp glass base Sheet is put in Muffle furnace, sinters 10h so that CaCO at 600～850 DEG C₃/SiO₂CaCO in compound particle₃Pyrolytic, The SiO of coarse structure and pore structure is had to deposition₂The high temp glass substrate of hollow ball coating.

Those skilled in the art, after considering description and putting into practice invention disclosed herein, will readily occur to its of the present invention Its embodiment.The application is intended to any modification, purposes or the adaptations of the present invention, these modification, purposes or Person's adaptations is followed the general principle of the present invention and includes the undocumented common knowledge in the art of the application Or conventional techniques means.Description and embodiments is considered only as exemplary, and true scope and spirit of the invention are by following Claim is pointed out.

It should be appreciated that the invention is not limited in precision architecture described above and illustrated in the accompanying drawings, and And various modifications and changes can carried out without departing from the scope.The scope of the present invention is only limited by appended claim.

Claims (4)

1. for an illuminating lamp under water, including lamp housing, lampshade and luminescence component, it is characterised in that described lamp housing is cylinder Shape, described luminescence component is arranged on lamp housing one end, and described lampshade is on described luminescence component, and described lamp housing top and bottom are joined Top cover and bottom, described top cover and bottom is had to be connected with the locking of described lamp housing by lock-screw.

Illuminating lamp the most according to claim 1, it is characterised in that be provided with sealing gasket between described lamp housing and top cover and bottom Circle.

Illuminating lamp the most according to claim 2, it is characterised in that described seal washer is waterproof elastic packing packing ring, Use sealant sealing.

Illuminating lamp the most according to claim 3, it is characterised in that described lampshade is antifog glass substrate.