PT107640B - PHOTOLUMINESCENT PART - Google Patents

Abstract

The present application describes photoluminescent parts composed of brushed or polished, brushed or polished prefabricated stainless steel parts with photoluminescent material dispersed within a matrix of polymeric material in the form of a semitransparent fine film deposited and / or printed on a TRIDIMENSIONAL STRUCTURE (3D). THESE PHOTOLUMINESCENT PARTS CAN BE USED IN THE BOTTOM / SIDE OF SWIMMING POOLS, BUILDING COVERINGS, WALL AND FLOOR TAPESTRIES, BATHROOMS AND KITCHEN WALLS, FRAMES AND WORKS OF ART, FURNITURE, LIGHTING PARTS, AND OTHERS.

Description

DESCRIPTION

Photoluminescent part

Technical Field The present application describes a three-dimensional stainless steel part with photoluminescent materials dispersed in a matrix of semitransparent thin-film polymeric material deposited and / or printed on the three-dimensional (3D) structure of the stainless steel part.

State of the art

Time Persistent Luminescence (LPT) is a phenomenon in which material continues to emit - usually in the visible range - for hours after the source of irradiation (or excitation) has been turned off. For excitation, electromagnetic irradiation can be used as visible or ultraviolet light, X-ray or gamma radiation.

Note that the term time persistent luminescence is used herein in a broad sense for historical reasons because the emission time is long due to thermally stimulated luminescence.

The use of materials with LPT properties in various areas of industry, particularly in emergency signaling, has been established for decades. In 1996, Matsuzwa T.et al [1] and Takasaki et al [2] discovered these properties in trivalent Dy-encoded alkaline earth aluminates, and ushered in a new era in the use of such materials. In these new materials the initial emission intensity and its lifetime after excitation is about two orders of magnitude higher than those that had been used before. That fact,

DESCRIPTION

Photoluminescent part

Technical Field The present application describes a three-dimensional stainless steel part with photoluminescent materials dispersed in a matrix of semitransparent thin-film polymeric material deposited and / or printed on the three-dimensional (3D) structure of the stainless steel part.

State of the art

Time Persistent Luminescence (LPT) is a phenomenon in which material continues to emit - usually in the visible range - for hours after the source of irradiation (or excitation) has been turned off. For excitation, electromagnetic irradiation can be used as visible or ultraviolet light, X-ray or gamma radiation.

Note that the term time persistent luminescence is used herein in a broad sense for historical reasons because the emission time is long due to thermally stimulated luminescence.

The use of materials with LPT properties in various areas of industry, particularly in emergency signaling, has been established for decades. In 1996, Matsuzwa T.et al [1] and Takasaki et al [2] discovered these properties in trivalent Dy-encoded alkaline earth aluminates, and ushered in a new era in the use of such materials. In these new materials the initial emission intensity and its lifetime after excitation is about two orders of magnitude higher than those that had been used before. This, coupled with the low cost of the raw materials needed to produce these pigments, has allowed it to expand its

use toys, in in between areas such as others. decoration, clothing, 0 parameter more important for characterize the emission persistent is the life time, or be the time elapsed after the end gives excitement, until the intensity bright

decrease the light detection limit of human eyes to about 100 times under scotopic conditions. The value commonly used by the emergency signaling industry as well as by various researchers is 0.32 mcd / m ² .

Although the mechanism that enables LPT cannot be adequately explained, in the present state it is accepted that the long decay time of persistent luminescence is due to the storage of excitation energy in traps (oxygen gaps and other intrinsic defects). , due to the presence of rare earth ions, then gradually released by the action of thermal energy.

The excitation required for persistent emission is achieved by exposure to sunlight and / or artificial light having a range of excitation wavelengths between 200 nm and 600 nm, the specific wavelength range being defined by the type of materials. with LPT properties and the transmittance of the film, or matrix, of material support. In the second case, an on / off control system may be used for the purposes of (a) minimizing power consumption and / or (b) achieving the desired emission intensity.

coupled with the low cost of the raw materials needed to produce these pigments, has allowed it to expand its

use toys, in in between areas such as others. decoration, clothing, 0 parameter more important for characterize the emission persistent is the life time, or be the time elapsed after the end gives excitement, until the intensity bright

decrease the light detection limit of human eyes to about 100 times under scotopic conditions. The value commonly used by the emergency signaling industry as well as by various researchers is 0.32 mcd / m ² .

Although the mechanism that enables LPT cannot be adequately explained, in the present state it is accepted that the long decay time of persistent luminescence is due to the storage of excitation energy in traps (oxygen gaps and other intrinsic defects). , due to the presence of rare earth ions, then gradually released by the action of thermal energy.

The excitation required for persistent emission is achieved by exposure to sunlight and / or artificial light having a range of excitation wavelengths between 200 nm and 600 nm, the specific wavelength range being defined by the type of materials. with LPT properties and the transmittance of the film, or matrix, of material support. In the second case, an on / off control system may be used for the purposes of (a) minimizing power consumption and / or (b) achieving the desired emission intensity.

Persistent emission color at the end of excitation is an intrinsic characteristic of the material used with LPT properties, and can be defined by the selective choice of said material during the preparation of the deposition / printing process.

In TWM396754UU a method for processing a high gloss photoluminescent film using a certain amount of photoluminescent pigments in solution with a transparent resin is disclosed so that a luminescent film can be formed which can be attached / added / bonded to various substrates. Analyzing the summary of the mentioned document, it is not possible to identify the processing technique of this material, nor is it mentioned the use of a specific type of polymer / acrylic solution with photoluminescent pigments, which allow the use of deposition / printing techniques such as spraying and / or by aerosol and / or ultrasound and / or centrifugation and / or spin coating of fine extrudates and / or dipping onto a stainless steel substrate.

DE102005061854A1 discloses a method for manufacturing photoluminescent security elements on glass panels, the main uses of which are building facades. In this method a solution is used which can be used in techniques such as screen printing or transfer printing processes to print the polymer matrix and its photoluminescent pigments. Mention is made of the use of a specific type of polymer / acrylic with photoluminescent pigments which permit their deposition / printing using techniques such as

Persistent emission color at the end of excitation is an intrinsic characteristic of the material used with LPT properties, and can be defined by the selective choice of said material during the preparation of the deposition / printing process.

In TWM396754UU a method for processing a high gloss photoluminescent film using a certain amount of photoluminescent pigments in solution with a transparent resin is disclosed so that a luminescent film can be formed which can be attached / added / bonded to various substrates. Analyzing the summary of the mentioned document, it is not possible to identify the processing technique of this material, nor is it mentioned the use of a specific type of polymer / acrylic solution with photoluminescent pigments, which allow the use of deposition / printing techniques such as spraying and / or by aerosol and / or ultrasound and / or centrifugation and / or spin coating of fine extrudates and / or dipping onto a stainless steel substrate.

DE102005061854A1 discloses a method for manufacturing photoluminescent security elements on glass panels, the main uses of which are building facades. In this method a solution is used which can be used in techniques such as screen printing or transfer printing processes to print the polymer matrix and its photoluminescent pigments. Mention is made herein of the use of a specific type of polymer / acrylic with photoluminescent pigments which permit their deposition / printing using techniques such as spraying and / or aerosol and / or ultrasound and / or centrifugation and / or spin coating of thin extrudates and / or dipping onto a stainless steel substrate. Therefore, the use of screen printing techniques or any transfer printing process or their use in security elements is not claimed.

EP1884554A1 discloses a method for developing luminescent inks that can be printed using inkjet and screen printing techniques and subsequently used to mark / identify objects. In this development, the use of a specific polymeric matrix comprising water and a cellulose derivative, ethylcellulose, in solution with rare earth doped alkaline earth fluorides is claimed. According to the claims of the document, the use of a solution comprising a photoluminescent pigment polymer / acrylic matrix is not referenced, nor is the use of stainless steel substrates referenced. The use of deposition / printing techniques such as spraying, and / or ultrasound and / or centrifugation and / or spinning of thin extrudates is also not mentioned in the mentioned document.

summary

It is the purpose of this application to describe a photoluminescent part characterized by comprising:

- Substrate made of stainless steel;

Semitransparent film consisting of encapsulated photoluminescent pigments dispersed in a matrix of polymeric or acrylic material having spray and / or aerosol and / or ultrasound properties and / or centrifugation and / or spin coating of fine extrudates and / or dipping onto a substrate. in stainless steel. Therefore, the use of screen printing techniques or any transfer printing process or their use in security elements is not claimed.

EP1884554A1 discloses a method for developing luminescent inks that can be printed using inkjet and screen printing techniques and subsequently used to mark / identify objects. In this development, the use of a specific polymeric matrix comprising water and a cellulose derivative, ethylcellulose, in solution with rare earth doped alkaline earth fluorides is claimed. According to the claims of the document, the use of a solution comprising a photoluminescent pigment polymer / acrylic matrix is not referenced, nor is the use of stainless steel substrates referenced. The use of deposition / printing techniques such as spraying, and / or ultrasound and / or centrifugation and / or spinning of thin extrudates is also not mentioned in the mentioned document.

summary

It is the purpose of this application to describe a photoluminescent part comprising:

- Stainless steel part;

Semitransparent film consisting of photoluminescent materials dispersed in a polymer / acrylic matrix.

transparency to electromagnetic radiation in the near and visible ultraviolet range,

Where said semitransparent film has a transmittance of less than 60% in the spectrum of electromagnetic radiation in the visible range.

In one embodiment of the photoluminescent part, the substrate is composed of stainless steel.

In another embodiment of the photoluminescent part, the substrate is comprised of areas between 2 and 25 cm ² .

In yet another embodiment of the photoluminescent part, the polymeric film comprises a semitransparent material.

In one embodiment of the photoluminescent part, the polymeric film is transparent to the near ultraviolet electromagnetic radiation range, which has a wavelength between 200 and 380 nm.

In another embodiment of the photoluminescent part, the polymeric film is transparent to the visible electromagnetic radiation range, which has a wavelength of 380 to 750 nm.

In yet another embodiment of the photoluminescent piece, the photoluminescent pigments are composed of divalent rare earth ion doped alkaline earth aluminates and trivalent ion co-doped.

In one embodiment of the photoluminescent part, the substrate is composed of stainless steel.

In another embodiment of the photoluminescent part, the substrate is comprised of areas between 2 and 25 cm ² .

In yet another embodiment of the photoluminescent part, the polymeric film comprises a semitransparent material.

In one embodiment of the photoluminescent part, the polymeric film is transparent to the near ultraviolet electromagnetic radiation range, which has a wavelength between 200 and 380 nm.

In another embodiment of the photoluminescent part, the polymeric film is transparent to the visible electromagnetic radiation range, which has a wavelength of 380 to 750 nm.

In yet another embodiment of the photoluminescent piece, the photoluminescent pigments are composed of divalent rare earth ion doped alkaline earth aluminates and trivalent ion co-doped.

In one embodiment of the photoluminescent piece, doping is performed with europium ions, Eu ²⁺ .

In another embodiment of the photoluminescent part, ion co-doping is performed with Dy ³⁺ and / or Tb ³⁺ and / or Tm ³⁺ and / or Nd ³⁺ .

In one embodiment of the photoluminescent piece, doping is performed with europium ions, Eu ²⁺ .

In another embodiment of the photoluminescent part, ion co-doping is performed with Dy ³⁺ and / or Tb ³⁺ and / or Tm ³⁺ and / or Nd ³⁺ .

In yet another embodiment of the photoluminescent piece, the photoluminescent pigments have a diameter between 5 and 65 µm.

In one embodiment of the photoluminescent part, the solution and / or suspension of polymeric material comprises a ratio of 1: 9, and / or 1:10, and / or 1:11 of chloroform and acrylic material.

In another embodiment of the photoluminescent part, the acrylic material used in the solution and / or suspension is methyl polymethacrylate (PMMA).

In yet another embodiment of the photoluminescent part, the aforementioned solution and / or suspension may be processed with another acrylic material which has a high transmittance in electromagnetic radiation in the near visible and ultraviolet range.

In one embodiment of the photoluminescent part, the ratio of acrylic varnish, diluent and activator is 1: 0.5: 0.5, respectively.

In another embodiment of the photoluminescent part, the acrylic lacquer consists of a mixture of butyl acetate (10-25%) and / or butanone (2.5-10%) and / or 2-methoxy-16

In yet another embodiment of the photoluminescent piece, the photoluminescent pigments have a diameter between 5 and 65 µm.

In one embodiment of the photoluminescent part, the solution and / or suspension of polymeric material comprises a ratio of 1: 9, and / or 1:10, and / or 1:11 of chloroform and acrylic material.

In another embodiment of the photoluminescent part, the acrylic material used in the solution and / or suspension is methyl polymethacrylate (PMMA).

In yet another embodiment of the photoluminescent part, the aforementioned solution and / or suspension may be processed with another acrylic material which has a high transmittance in electromagnetic radiation in the near visible and ultraviolet range.

In one embodiment of the photoluminescent part, the ratio of acrylic varnish, diluent and activator is 1: 0.5: 0.5, respectively.

In another embodiment of the photoluminescent part, the acrylic lacquer consists of a mixture of butyl acetate (10-25%) and / or butanone (2.5-10%) and / or 2-methoxy-1-methylethyl (2.5 -10%) and / or xylene (0.1-2.5%) and / or bis (1,2,2,6,6-pentamethyl-4-piperidyl) sebacate (0.1-1%) and / or straight or branched chain alkyl 3- [3- (2H-benzotriazol-2-yl) -5- (1,1-dimethylethyl) -4-hydroxyphenyl] propanoates, which may contain from 7 to 9 carbons (0.11% ) and / or isobutyl methacrylate (0.1-1%) and / or methyl (1,2,2,6,6pentamethyl-4-piperidyl sebacate) (0.1-1%).

methylethyl (2.5-10%) and / or xylene (0.1-2.5%) and / or bis (1,2,2,6,6-pentamethyl-4-piperidyl) sebacate (0.1- 1%) and / or 3 - [3- (2H-benzotriazol-2-yl) -5- (1,1-dimethylethyl) -4-hydroxyphenyl] propanoates of straight or branched chain alkyl, which may contain from 7 to 9 carbons (0.11%) and / or isobutyl methacrylate (0.1-1%) and / or methyl (1,2,2,6,6pentamethyl-4-piperidyl sebacate) (0.1-1%).

In yet another embodiment of the photoluminescent part, the diluent comprises a mixture of n-butyl acetate (50-100%) and / or naphtha (25-50%) and / or 2-methoxy-1-methylethyl acetate ( 2.5-10%).

In one embodiment of the photoluminescent part, the activator comprises a mixture of diisocyanate hexamethylene oligomers (50-100%) and / or nbutyl acetate (0.1-20%) and / or 2-methoxy-1-acetate. methylethyl (1025%) and / or 2-butoxyethyl acetate (2.5-10%) and / or naphtha (0.1-5%).

In another embodiment the photoluminescent films are deposited and / or printed on a piece of stainless steel between 10 and 100 µm thick.

In yet another embodiment of the photoluminescent piece, the photoluminescent pigments have emission intensities of the order of 0.1-0.3 cd / m ² during the first hour of emission.

In one embodiment of the photoluminescent piece, the excitation of photoluminescent pigments may be done by sunlight and / or ambient light.

In yet another embodiment of the photoluminescent part, the diluent comprises a mixture of n-butyl acetate (50-100%) and / or naphtha (25-50%) and / or 2-methoxy-1-methylethyl acetate ( 2.5-10%).

In one embodiment of the photoluminescent part, the activator comprises a mixture of diisocyanate hexamethylene oligomers (50-100%) and / or nbutyl acetate (0.1-20%) and / or 2-methoxy-1-acetate. methylethyl (1025%) and / or 2-butoxyethyl acetate (2.5-10%) and / or naphtha (0.1-5%).

In another embodiment the photoluminescent films are deposited and / or printed on a piece of stainless steel between 10 and 100 µm thick.

In yet another embodiment of the photoluminescent piece, the photoluminescent pigments have emission intensities of the order of 0.1-0.3 cd / m ² during the first hour of emission.

In one embodiment of the photoluminescent piece, the excitation of photoluminescent pigments may be done by sunlight and / or ambient light.

In another embodiment of the photoluminescent piece, excitation of photoluminescent pigments may be performed using an on / off excitation system using light sources at intervals comprising near ultraviolet radiation.

In another embodiment of the photoluminescent piece, excitation of photoluminescent pigments may be performed using an on / off excitation system using light sources at intervals comprising near ultraviolet radiation.

In yet another photoluminescent, photoluminescent embodiment of the excitation mentioned above may be made using some additional electromagnetic.

Through part filters the pigments of the present radiation system also describe the process for obtaining the photoluminescent part comprising the following steps:

- Preparation of mixtures of polymeric / acrylic material and photoluminescent pigments for depositing and / or printing;

- Deposition / printing of the mixture using spray technology with a distance between 10 mm and 250 mm;

- Thermally cured photoluminescent film through a temperature gradient between 40 and 80 ° C for 40 to 90 minutes.

Also disclosed in this application is the use of the photoluminescent piece on the bottom / side of swimming pools, building covers, wall and floor tapestries, bathroom and kitchen walls, paintings and artwork, furniture, lighting fixtures, and others.

General description

In yet another photoluminescent, photoluminescent embodiment of the excitation may be made mentioned above using some additional electromagnetic.

Through part filters the pigments of the present radiation system also describe the process for obtaining the photoluminescent part comprising the following steps:

- Preparation of mixtures of polymeric / acrylic material and photoluminescent pigments for depositing and / or printing;

- Deposition / printing of the mixture using spray technology with a distance between 10 mm and 250 mm;

- Thermally cured photoluminescent film through a temperature gradient between 40 and 80 ° C for 40 to 90 minutes.

Also disclosed in this application is the use of the photoluminescent piece on the bottom / side of swimming pools, building covers, wall and floor tapestries, bathroom and kitchen walls, paintings and artwork, furniture, lighting fixtures, and others.

General description

The present application describes photoluminescent parts composed of brushed / polished stainless steel parts, preferably in the form of plates, pellets or tiles, with a thin film formed on the three-dimensional (3D) structure of the stainless steel part forming plates, pellets or tiles. photoluminescent.

The present application describes photoluminescent parts composed of brushed / polished stainless steel parts, preferably in the form of plates, pellets or tiles, with a thin film formed on the three-dimensional (3D) structure of the stainless steel part forming photoluminescent plates, pellets or tiles. .

These photoluminescent parts can be used on the bottom / side of swimming pools, building covers, wall and floor tapestry, bathroom and kitchen walls, paintings and artwork, furniture, lighting fixtures and others.

Photoluminescent film is composed of a transparent polymeric / acrylic material for the near and visible ultraviolet electromagnetic radiation range, and the photoluminescent pigments may have different transmittance percentages (0-80%) to suit the desired purpose.

The photoluminescent part is excited by a specific wavelength which is within the range of near and visible ultraviolet electromagnetic radiation allowing the emission of visible electromagnetic radiation for several minutes when it is placed in places completely devoid of light. In this way, the photoluminescent part is capable of being excited by an on / off system using light sources in the near ultraviolet range and, if necessary, some wavelength filters.

The wavelength of radiation emitted from the photoluminescent part can be adjusted on the RGB spectrum.

These photoluminescent parts can be used on the bottom / side of swimming pools, building covers, wall and floor tapestry, bathroom and kitchen walls, paintings and artwork, furniture, lighting fixtures and others.

Photoluminescent film is composed of a transparent polymeric / acrylic material for the near and visible ultraviolet electromagnetic radiation range, and the photoluminescent pigments may have different transmittance percentages (0-80%) to suit the desired purpose.

The photoluminescent part is excited by a specific wavelength which is within the range of near and visible ultraviolet electromagnetic radiation allowing the emission of visible electromagnetic radiation for several minutes when it is placed in places completely devoid of light. In this way, the photoluminescent part is capable of being excited by an on / off system using light sources in the near ultraviolet range and, if necessary, some wavelength filters.

The wavelength of radiation emitted from the photoluminescent part can be adjusted in the RGB (red, green, blue) spectrum, and it is possible to obtain functional parts with a specific radiation emission and / or adjustable radiation emission from violet to yellow. red, and / or pieces with different colors in different spatial locations. Photoluminescent pigments are encapsulated within a matrix of thermally curable polymeric / acrylic material and / or a support structure (red, green, blue) and functional parts with specific radiation emission and / or adjustable radiation can be obtained. emission from violet to red, and / or parts with different colors in different spatial locations. Photoluminescent pigments are encapsulated within a matrix of thermally curable polymeric / acrylic material and / or a polymeric support structure and / or porous polymeric film that is transparent to electromagnetic radiation in the near and visible ultraviolet range, ensuring the necessary radiation to the excitation of photoluminescent material, electromagnetic emitted radiation observation pigments

This piece by encapsulation gives a longer photoluminescent lifetime due to the absence of intersections between the photoluminescent material and the environment, thereby decreasing its degradation over time.

Thus, the purpose of this technology is to obtain photoluminescent parts composed of a stainless steel substrate and photoluminescent pigments encapsulated within a matrix of thermally curable polymer / acrylic material and / or a polymeric support structure and / or porous film. which is transparent to electromagnetic radiation in near and visible ultraviolet.

Brief Description of the Figures

For ease of interpretation of the application three figures are attached to this document, which represent embodiments, however, which are not intended to limit the object of this embodiment.

polymeric and / or porous polymeric film that is transparent to electromagnetic radiation in the near and visible ultraviolet range, ensuring the radiation necessary for excitation of photoluminescent material, electromagnetic emitted radiation observation pigments

This piece by encapsulation gives a longer photoluminescent lifetime due to the absence of intersections between the photoluminescent material and the environment, thereby decreasing its degradation over time.

Thus, the purpose of this technology is to obtain photoluminescent parts composed of a stainless steel substrate and photoluminescent pigments encapsulated within a matrix of thermally curable polymer / acrylic material and / or a polymeric support structure and / or porous film. which is transparent to electromagnetic radiation in near and visible ultraviolet.

Brief Description of the Figures

For ease of interpretation of the application three figures are attached to this document, which represent embodiments, however, which are not intended to limit the object of this embodiment.

Figure 1 shows an exploded view of the photoluminescent part structure in which the reference numerals represent:

1- Stainless steel insert / tile / piece;

2- Film of polymeric / acrylic material with photoluminescent pigments.

Figure 1 shows an exploded view of the photoluminescent part structure in which the reference numerals represent:

1- Stainless steel insert / tile / piece;

2- Film of polymeric / acrylic material with photoluminescent pigments.

Figure 2a) shows a 3D perspective view of an embodiment of the photoluminescent stainless steel insert and / or insert / tile / plate.

Figure 2b) shows a sectional view of the same embodiment of the functional photoluminescent part.

Figure 3 shows a three-dimensional embodiment of a stainless steel plate.

Description of embodiments

Substrate and / or product - Three-dimensional (3D) stainless steel insert and / or functional part, tile and / or plate with different sizes and geometries for different applications.

3D stainless steel inserts / tiles / parts, as shown in Figure 3, have a wide variety of surface coating decoration applications. Stainless steel is highly resistant to oxidation, corrosion, temperature and humidity and for these reasons is a material of choice in applications requiring high physical, chemical and mechanical performance. Its resistance allows the

Figure 2a) shows a 3D perspective view of an embodiment of the photoluminescent stainless steel insert and / or insert / tile / plate.

Figure 2b) shows a sectional view of the same embodiment of the functional photoluminescent part.

Figure 3 shows a three-dimensional embodiment of a stainless steel plate.

Description of embodiments

Substrate and / or product - Three-dimensional (3D) stainless steel insert and / or functional part, tile and / or plate with different sizes and geometries for different applications.

3D stainless steel inserts / tiles / parts, as shown in Figure 3, have a wide variety of surface coating decoration applications. Stainless steel is highly resistant to oxidation, corrosion, temperature and humidity and for these reasons is a material of choice in applications requiring high physical, chemical and mechanical performance. Its strength allows its use at high and low temperatures without any loss of efficiency in terms of its mechanical characteristics. These specificities allow a high adhesion between the substrate and the deposition / printing of polymeric / acrylic dispersions and photoluminescent materials such as microparticles, gels and their smooth surface and conditions required for thin films. Additionally, slightly porous combines its use at high and low temperatures without any loss of efficiency in terms of its mechanical characteristics. These specificities allow high adhesion between the substrate and the deposition / printing of polymeric / acrylic dispersions and photoluminescent materials such as microparticles, gels and thin films. In addition, their smooth, slightly porous surface meets the conditions necessary for these stainless steel parts to be used in environments requiring compliance with the highest hygiene standards, such as restaurants, kitchens, hospitals, laboratories and decorative applications. specifically refers to this application. This easy-to-clean material offers aesthetic durability as it does not darken or laminate.

Photoluminescent material deposited / printed on tiles / inserts / plates and functional parts

Materials with LPT properties used in this application may be, but not exclusively, based on divalent rare earth ion (TR) doped alkaline earth aluminate matrices, which may be, for example, europium, Eu ²⁺ , and co-doped. with trivalent TR ions, for example DY ³⁺ , Tb ³⁺ , Tm ³⁺ and Nd ³⁺ . These materials are commercially available in various formulations and grain sizes, allowing for persistent light emission in the visible spectrum range with a lifetime of several hours, initial emission intensities of the order of several cd / m ² and persistent intensities. in the order of 0.1-0.3 cd / m ² during the first hour.

These stainless steel parts are used in environments that require compliance with the highest hygiene standards, such as restaurants, kitchens, hospitals, laboratories and decorative applications specifically referred to in this application. This easy-to-clean material offers aesthetic durability as it does not darken or laminate.

Photoluminescent material deposited / printed on tiles / inserts / plates and functional parts

Materials with LPT properties used in this application may be, but not exclusively, based on divalent rare earth ion (TR) doped alkaline earth aluminate matrices, which may be, for example, europium, Eu ²⁺ , and co-doped. with trivalent TR ions, for example DY ³⁺ , Tb ³⁺ , Tm ³⁺ and Nd ³⁺ . These materials are commercially available in various formulations and grain sizes, allowing for persistent light emission in the visible spectrum range with a lifetime of several hours, initial emission intensities of the order of several cd / m ² and persistent intensities. in the order of 0.1-0.3 cd / m ² during the first hour.

The problems associated with depositing / printing on a surface such as stainless steel, where there is a need to maintain characteristic identity, are related to the high grain size available in materials between 5-65 pm and its intrinsic opacity. Opacity reduction requires the use of very thin and dense layers of material to maintain the surface identity of the part. In addition, the

The problems associated with depositing / printing on a surface such as stainless steel, where there is a need to maintain characteristic identity, are related to the high grain size available in materials between 5-65 pm and its intrinsic opacity. Opacity reduction requires the use of very thin and dense layers of material to maintain the surface identity of the part. In addition, the grain size of the photoluminescent pigments makes surface adhesion difficult.

To overcome these problems with pigments with LPT properties, they are embedded in a polymer / acrylic matrix before being deposited on the 3D stainless steel substrate. The most important features of this matrix are its transmittance in the UV-VIS range for the reasons already described, high adhesion to the stainless steel substrate and high photochemical stability which ensures its durability when exposed to such radiation. The polymeric or acrylic matrix provides support for the photoluminescent material. Photoluminescent pigments are encapsulated in the polymeric / acrylic film structure, obtaining dispersion and individual encapsulation of the pigments.

The pigments are incorporated into the polymeric / acrylic film structure from their previous dispersion in a solution of the polymeric / acrylic material and its solvent and dispersed using intensive stirring by any of the usual means which may be ultrasonic bath, magnetic stirrer, or others. Then the material suspension deposition / printing process is performed and a possible grain size of the photoluminescent pigments makes it difficult to adhere to the surface.

To overcome these problems with pigments with LPT properties, they are embedded in a polymer / acrylic matrix before being deposited on the 3D stainless steel substrate. The most important features of this matrix are its transmittance in the UV-VIS range for the reasons already described, high adhesion to the stainless steel substrate and high photochemical stability which ensures its durability when exposed to such radiation. The polymeric or acrylic matrix provides support for the photoluminescent material. Photoluminescent pigments are encapsulated in the polymeric / acrylic film structure, obtaining dispersion and individual encapsulation of the pigments.

The pigments are incorporated into the polymeric / acrylic film structure from their previous dispersion in a solution of the polymeric / acrylic material and its solvent and dispersed using intensive stirring by any of the usual means which may be ultrasonic bath, magnetic stirrer, or others. Then the material suspension deposition / printing process and a possible coating of additional material using a hardening varnish is provided to provide better impact and scratch resistance.

Photoluminescent insert / tile / steel plate and encapsulation of functional parts

For the protection of deposited / printed materials, it is additional material coating using a hardening varnish to provide better impact and scratch resistance.

Photoluminescent insert / tile / steel plate and encapsulation of functional parts

For the protection of deposited / printed materials, commercial polymeric / acrylic encapsulating agents typically found commercially in solution and / or suspension form, glass or polymeric barrier films with specific transmittance characteristics can be used in near and visible ultraviolet electromagnetic spectra. , so as not to compromise the excitation of photoluminescent materials and subsequent emission of electromagnetic radiation in the visible (efficiency) range.

The encapsulation provides protection against the environment and chemicals to increase the life of the photoluminescent insert / tile / plate and also to allow surface cleaning. Encapsulation is done by direct application of acrylic encapsulating agent to the 3D surface of the matrix by wet deposition / printing techniques, or direct lamination techniques for polymeric / acrylic barrier films or by application of glass encapsulation techniques.

Encapsulation allows the functional part and / or insert / tile for decorative applications to exhibit photoluminescent properties while maintaining the steel identity aspect. Commercial polymeric / acrylic encapsulating agents typically found commercially in solution and / or form may be used. suspension, glass or polymeric barrier films with specific transmittance characteristics on near and visible ultraviolet electromagnetic spectra, so as not to compromise the excitation of photoluminescent materials and subsequent emission of electromagnetic radiation in the visible (efficiency) range.

The encapsulation provides protection against the environment and chemicals to increase the life of the photoluminescent insert / tile / plate and also to allow surface cleaning. Encapsulation is done by direct application of acrylic encapsulating agent to the 3D surface of the matrix by wet deposition / printing techniques, or direct lamination techniques for polymeric / acrylic barrier films or by application of glass encapsulation techniques.

Encapsulation enables the functional part and / or insert / tile / plate for decorative applications to exhibit photoluminescent properties while maintaining the identity aspect of the stainless steel to be handled, processed and packaged in typical processes for decorative application processes.

Functional stainless steel insert / tile / plate for decorative applications with deposited / printed photoluminescent film has scratch resistance properties comparable to stainless steel without deposited / printed photoluminescent film, water resistance eg rainwater, water supply of the stainless mesh to be handled, processed and packaged in typical processes for decorative application processes.

Functional stainless steel insert / tile / plate for decorative applications with deposited / printed photoluminescent film has scratch resistance properties comparable to stainless steel without deposited / printed photoluminescent film, water resistance eg rainwater, water supply slightly acidic pH, which may be a pH of 4, or basic, which may be a pH of 9, and pool water with and without chlorine ions, contact resistance when a suitable cleaning cloth is used and glass and stainless steel compatible cleaning chemicals.

Light intensity control

In addition to the process described in the previous section, where the intensity of persistent light emission is controlled by the density of the deposited material, an external method for use independently or in combination to achieve greater intensity control is described herein. persistent issue.

In situations where, for decorative purposes, a persistent luminous intensity of greater amplitude than that allowed by the decay time characteristic of the material used is required, a variable non-intrusive excitation process over time may be employed, such as as: a persistent emission intensity decreases over time, approximately according to an exponential decay from initial intensity to residual intensity detection.

slightly acidic pH, which may be a pH of 4, or basic, which may be a pH of 9, and chlorinated ion-free and pool water, contact resistance when a suitable cleaning cloth is used and cleaning chemicals compatible with glass and stainless steel.

Light intensity control

In addition to the process described in the previous section, where the intensity of persistent light emission is controlled by the density of the deposited material, an external method for use independently or in combination to achieve greater intensity control is described herein. persistent issue.

In situations where, for decorative purposes, a persistent luminous intensity of greater amplitude than that allowed by the decay time characteristic of the material used is required, a variable non-intrusive excitation process over time may be employed, such as as: a persistent emission intensity decreases over time, approximately according to an exponential decay from initial intensity to residual intensity detection. Thus, during the first few minutes after excitation, the intensity of persistent emission decreases very rapidly, not allowing high luminance levels to be maintained for more than a few minutes, making it difficult to detect emissions under mesopic conditions.

This method uses a source of electromagnetic radiation in the near ultraviolet spectral range, the spectral brightness of which is not visible to the human eye, so that

Thus, during the first few minutes after excitation, the intensity of persistent emission decreases very rapidly, not allowing high luminance levels to be maintained for more than a few minutes, making it difficult to detect emissions under mesopic conditions.

This method uses a source of electromagnetic radiation in the near ultraviolet spectral range, the spectral brightness of which is not visible to the human eye, so that at predefined intervals (on / off cycles) it can excite the sample for as long as necessary. persistent intensity return to desired value. This is achieved by coupling the excitation source to a power control circuit having: a) frequency and charge cycle programming and / or b) data sending system allowing frequency and charge cycle control, depending on of the value returned from a light sensor. In both cases, the frequency and charge cycle adjustment is such that they maintain the persistent emission intensity within the minimum and maximum values.

Final Object

The final object is a functional part and / or functional stainless steel insert / tile / plate with photoluminescent or LPT properties in the 3D surface structure for decorative applications.

This functional part comprises a stainless steel tile and / or tile / chip / plate and a photoluminescent film comprised of a matrix of polymeric / acrylic material and photoluminescent pigments.

Preset time intervals (cycles on / off) may excite the sample for as long as the persistent intensity returns to the desired value. This is achieved by coupling the excitation source to a power control circuit having: a) frequency and charge cycle programming and / or b) data sending system allowing frequency and charge cycle control, depending on of the value returned from a light sensor. In both cases, the frequency and charge cycle adjustment is such that they maintain the persistent emission intensity within the minimum and maximum values.

Final Object

The final object is a functional part and / or functional stainless steel insert / tile / plate with photoluminescent or LPT properties in the 3D surface structure for decorative applications.

This functional part comprises a stainless steel tile and / or tile / chip / plate and a photoluminescent film comprised of a matrix of polymeric / acrylic material and photoluminescent pigments.

In order to maintain the characteristic appearance / appearance of stainless steel, the photoluminescent film must be transparent and / or semi-transparent. It is understood throughout this text that a film is semitransparent if the concentration of photoluminescent pigments in the polymer / acrylic material matrix is high, resulting in a deposition / deposition of thin film deposited / printed less than 60% in the spectrum of electromagnetic radiation in the visible range. .

In order to maintain the characteristic appearance / appearance of stainless steel, the photoluminescent film must be transparent and / or semi-transparent. It is understood throughout this text that a film is semitransparent if the concentration of photoluminescent pigments in the polymer / acrylic material matrix is high, resulting in a deposition / deposition of thin film deposited / printed less than 60% in the spectrum of electromagnetic radiation in the visible range. .

This stainless steel part emits electromagnetic radiation in the visible range upon completion of radiation excitation from the near visible and / or ultraviolet spectrum range. The persistent light emission intensity is such that it allows visible light intensities of 0.3 cd / m ² when the frame is placed in areas with little or no ambient light. The color of the emission depends on the LPT properties of the deposited / printed material on the functional stainless steel tablet and / or tile.

Deposition Techniques

The polymer / acrylic matrix is deposited using wet deposition / printing techniques, and the material is subsequently cured to evaporate the solvent from solution and / or suspension by thermal curing and / or ultraviolet radiation techniques.

Deposition / printing of the solution and / or suspension may be by solution coating and / or suspension techniques for low viscosity materials such as ultrasonic coating, aerosol coating or spray coating.

This stainless steel part emits electromagnetic radiation in the visible range upon completion of radiation excitation from the near visible and / or ultraviolet spectrum range. The persistent light emission intensity is such that it allows visible light intensities of 0.3 cd / m ² when the frame is placed in areas with little or no ambient light. The color of the emission depends on the LPT properties of the deposited / printed material on the functional stainless steel tablet and / or tile.

Deposition Techniques

The polymer / acrylic matrix is deposited using wet deposition / printing techniques, and the material is subsequently cured to evaporate the solvent from solution and / or suspension by thermal curing and / or ultraviolet radiation techniques.

Deposition / printing of the solution and / or suspension may be by solution coating and / or suspension techniques for low viscosity materials such as ultrasonic coating, aerosol coating or spray coating.

Deposition / printing techniques for high viscosity solutions and suspensions such as dip coating, spin coating and / or thin extruded spin coating are alternatives for the production of photoluminescent film.

The particulate solution and / or suspension used for deposition / printing by the aforementioned techniques is prepared based on the level of

Deposition / printing techniques for high viscosity solutions and suspensions such as dip coating, spin coating and / or thin extruded spin coating are alternatives for the production of photoluminescent film.

The particulate solution and / or suspension used for deposition / printing by the aforementioned techniques is prepared based on the level of photoluminescence and transmittance that must be present in the thin film deposited / printed on pellet and / or tile and / or Functional stainless steel plate. To ensure the preservation of the stainless steel identity it is necessary that the concentration of pigments in the solution and / or suspension and the deposition / printing process used is such that the pigment density on the substrate is low enough to ensure high transmittance without affect the desired emission intensity. This emission intensity can also be externally controlled by the method described in the previous sections. To optimize pigment dispersion and stainless steel adhesion of the polymer / acrylic matrix, various additives such as suspension stabilizers, viscosity modifiers, dispersants and hardeners are added to optimize the homogeneity of the three-dimensional pigment distribution in the polymer matrix. solution and / or suspension deposited / printed on pellet and / or tile and / or functional stainless steel plate.

Photoluminescent photoluminescent thermal cure incorporated into the film constituent material does not alter the properties of the particles, so that they are a three-dimensional structure resulting from photoluminescence and transmittance that must be present in the thin film deposited / printed on pellet and / or tile and / or Functional stainless steel plate. To ensure the preservation of the stainless steel identity it is necessary that the concentration of pigments in the solution and / or suspension and the deposition / printing process used is such that the pigment density on the substrate is low enough to ensure high transmittance without affect the desired emission intensity. This emission intensity can also be externally controlled by the method described in the previous sections. In order to optimize pigment dispersion and adhesion to stainless steel of the polymer / acrylic matrix, various additives such as suspension stabilizers, viscosity modifiers, dispersants and hardeners are added in order to optimize the homogeneity of the three-dimensional distribution of pigments in the matrix. solution and / or suspension deposited / printed on pellet and / or tile and / or functional stainless steel plate.

Thermal curing of the photoluminescent film constituent material does not alter the photoluminescent properties of the particles, so that they are incorporated into the three-dimensional structure resulting from curing the process of the acrylic / polymeric matrix material. The transmittance of materials that can be used as matrices allows the excitation of photoluminescent pigments, maintaining the characteristic color of stainless steel after deposition / printing.

cure the process of the acrylic / polymeric matrix material. The transmittance of materials that can be used as matrices allows the excitation of photoluminescent pigments, maintaining the characteristic color of stainless steel after deposition / printing.

References

1. A new long phosphorescent phosphor with high brightness, SrAl ₂ O ₄ : Eu ²⁺ , Dy ³⁺ . Matsuzawa T. , et al. 143, 1996, J. Electrochem. Soc., Pp. 2670-2673.

2. Long-lasting afterglow characteristics of Eu, Dy codoped SrO-Al ₂ O3 phosphor. Takasaki, H., Tanabe, S. and Hanada, T. 1996, J. Ceram. Soc. Jpn., Vol. 104, pp. 322-326.

The invention is, of course, by no means limited to the described embodiments, and one of ordinary skill in the art can anticipate or design various modifications within the scope of the appended claims.

The described embodiments may be combined with each other. The following claims define further preferred embodiments of the present invention.

Lisbon, April 20, 2015

References

1. A new long phosphorescent phosphor with high brightness, SrAl ₂ O ₄ : Eu ²⁺ , Dy ³⁺ . Matsuzawa T. , et al. 143, 1996, J. Electrochem. Soc., Pp. 2670-2673.

2. Long-lasting afterglow characteristics of Eu, Dy codoped SrO-Al ₂ O3 phosphor. Takasaki, H., Tanabe, S. and Hanada, T. 1996, J. Ceram. Soc. Jpn., Vol. 104, pp. 322-326.

The invention is, of course, by no means limited to the described embodiments, and one of ordinary skill in the art can anticipate or design various modifications within the scope of the appended claims.

The described embodiments may be combined with each other. The following claims define further preferred embodiments of the present invention.

Lisbon, February 22, 2017.

Claims (23)

1. Photoluminescent part characterized by understanding: - Substrate made of stainless steel; Film consisting of encapsulated photoluminescent pigments dispersed in a matrix of polymeric or acrylic material with properties of transparency to electromagnetic radiation in the near and visible ultraviolet range, Where said film has a transmittance of less than 60% in the spectrum of electromagnetic radiation in the visible range. Photoluminescent part according to the preceding claim, characterized in that the substrate comprises areas between 2 and 25 cm ² . Photoluminescent part according to any one of the preceding claims, characterized in that the polymeric film comprises a semitransparent material. Photoluminescent part according to any one of the preceding claims, characterized in that the polymeric film is transparent to the near ultraviolet electromagnetic radiation range, which has a wavelength between 200 and 380 nm. Photoluminescent part according to any one of the preceding claims, characterized in that the polymeric film is transparent to the range of visible electromagnetic radiation which has a wavelength between 380 and 750 nm. 1. Photoluminescent part characterized by understanding: - Substrate made of stainless steel; Semitransparent film consisting of encapsulated photoluminescent pigments dispersed in a polymeric or acrylic matrix. 2 . Photoluminescent part in a deal with the claim former, characterized per the substrate be composed per areas between 2 and 25 cm ² . 3 Photoluminescent part in a deal with Any of them of preceding claims, characterized in that the polymeric film comprises a semitransparent material. Photoluminescent part according to any one of the preceding claims, characterized in that the polymeric film is transparent to the near ultraviolet electromagnetic radiation range, which has a wavelength between 200 and 380 nm. Photoluminescent part according to any one of the preceding claims, characterized in that the polymeric film is transparent to the range of visible electromagnetic radiation which has a wavelength between 380 and 750 nm. Photoluminescent part according to any one of the preceding claims, characterized in that the photoluminescent pigments are composed of divalent rare earth ion doped alkaline earth aluminates and co-doped with trivalent ions. Photoluminescent part according to any one of the preceding claims, characterized in that the photoluminescent pigments are composed of divalent rare earth ion doped alkaline earth aluminates and co-doped with trivalent ions. Photoluminescent part according to claim 6, characterized in that the doping is carried out with europium ions. Photoluminescent part according to claim 6, characterized in that the ion co-doping is performed with Dy ³⁺ and / or Tb ³⁺ and / or Tm ³⁺ and / or Nd ³⁺ . Photoluminescent part according to any one of the preceding claims, characterized in that the photoluminescent pigments have a diameter between 5 and 65 µm. Photoluminescent part according to any one of the preceding claims, characterized in that the photoluminescent pigments have emission intensities of the order of 0.1-0.3 cd / m ² during the first hour of emission. Photoluminescent part according to any one of the preceding claims, characterized in that the excitation of photoluminescent pigments may be made by sunlight and / or ambient light. Photoluminescent part according to any one of the preceding claims, characterized in that the excitation of photoluminescent pigments is performed using Photoluminescent part according to any one of the preceding claims, characterized in that the photoluminescent pigments are composed of divalent rare earth ion doped alkaline earth aluminates and co-doped with trivalent ions. Photoluminescent part according to any one of the preceding claims, characterized in that the doping is carried out with europium ions. Photoluminescent part according to any one of the preceding claims, characterized in that the ion co-doping is performed with Dy ³⁺ and / or Tb ³⁺ and / or Tm ³⁺ and / or Nd ³⁺ . Photoluminescent part according to any one of the preceding claims, characterized in that the photoluminescent pigments have a diameter between 5 and 65 µm. Photoluminescent part according to any one of the preceding claims, characterized in that the solution of polymeric material comprises a ratio of 1: 9 or 1:10 or 1:11 of chloroform and acrylic material. Photoluminescent part according to the preceding claim, characterized in that the acrylic material is methyl polymethacrylate. Photoluminescent part according to any one of the preceding claims, characterized in that the acrylic material used in the polymeric material solution is processed with high transmittance in electromagnetic radiation in the visible and near ultraviolet range. Photoluminescent part according to any one of the preceding claims, characterized in that the doping is carried out with europium ions. Photoluminescent part according to any one of the preceding claims, characterized in that the ion co-doping is performed with Dy ³⁺ and / or Tb ³⁺ and / or Tm ³⁺ and / or Nd ³⁺ . Photoluminescent part according to any one of the preceding claims, characterized in that the photoluminescent pigments have a diameter between 5 and 65 µm. Photoluminescent part according to any one of the preceding claims, characterized in that the solution of polymeric material comprises a ratio of 1: 9 or 1:10 or 1:11 of chloroform and acrylic material. Photoluminescent part according to the preceding claim, characterized in that the acrylic material is methyl polymethacrylate. Photoluminescent part according to any one of the preceding claims, characterized in that the acrylic material used in the polymeric material solution is processed with high transmittance in electromagnetic radiation in the visible and near ultraviolet range. Photoluminescent part according to one of the preceding claims, characterized in that the proportion of acrylic varnish, diluent and activator is 1: 0.5: 0.5, respectively. with interval fonts near. light with on / off cycles that comprise ultraviolet radiation Photoluminescent part according to any one of the preceding claims, characterized in that the excitation of photoluminescent pigments is made using additional electromagnetic filters. A process for obtaining a photoluminescent part as described in any one of the preceding claims, characterized in that it comprises the following steps: Preparation of mixtures of polymeric / acrylic material and photoluminescent pigments for depositing and / or printing; Deposition / printing of the mixture using spray technology with a distance of between 10 mm and 250 mm; Thermally cured photoluminescent film through a temperature gradient between 40 and 80 ° C for 40 to 90 minutes. Use of a photoluminescent part as described in any one of claims 1 to 13 characterized in that it is used in the bottom / side of swimming pools, building covers, wall and floor tapestry, bathroom and kitchen walls, paintings and works. of art, furniture, lighting parts. Lisbon, February 22, 2017. Photoluminescent part according to one of the preceding claims, characterized in that the proportion of acrylic varnish, diluent and activator is 1: 0.5: 0.5, respectively. Photoluminescent part according to any one of the preceding claims, characterized in that the acrylic material consists of a mixture of n-butyl acetate (10-25%) and / or butanone (2.5-10%) and / or 2-methoxy-1-methylethyl (2.5-10%) and / or xylene (0.1-2.5%) and / or bis (1,2,2,6,6-pentamethyl-4-piperidyl) sebacate ( 0.1-1%) and / or 3 - [3- (2H-benzotriazol-2-yl) -5- (1,1-dimethylethyl) -4-hydroxyphenyl] propanoates of straight or branched chain alkyls, which may contain from 7 to 9 carbons (0.1-1%) and / or isobutyl methacrylate (0.1-1%) and / or methyl (1,2,2,6,6-pentamethyl-4-piperidyl sebacate) (0 , 11%). Photoluminescent part according to any one of the preceding claims, characterized in that the diluent comprises a mixture of n-butyl acetate (50100%) and / or naphtha (25-50%) and / or 2-methoxy-1-methoxy. methylethyl (2.5-10%). Photoluminescent part according to any one of the preceding claims, characterized in that the activator comprises a mixture of diisocyanate hexamethylene oligomers (50-100%) and / or n-butyl acetate (0.1-20%) and / or 2-methoxy-1-methylethyl (10-25%) and / or 2-butoxyethyl acetate (2.5-10%) and / or naphtha (0.1-5%). Photoluminescent part according to any one of the preceding claims, characterized in that the acrylic material consists of a mixture of n-butyl acetate (10-25%) and / or butanone (2.5-10%) and / or 2-methoxy-1-methylethyl (2.5-10%) and / or xylene (0.1-2.5%) and / or bis (1,2,2,6,6-pentamethyl-4-piperidyl) sebacate ( 0.1-1%) and / or straight or branched chain alkyl 3- [3- (2H-benzotriazol-2-yl) -5- (1,1-dimethylethyl) -4-hydroxyphenyl] propanoates, which may contain from 7 to 9 carbons (0.1-1%) and / or isobutyl methacrylate (0.1-1%) and / or methyl (1,2,2,6,6-pentamethyl-4-piperidyl sebacate) (0 , 11%). Photoluminescent part according to any one of the preceding claims, characterized in that the diluent comprises a mixture of n-butyl acetate (50100%) and / or naphtha (25-50%) and / or 2-methoxy-1-methoxy. methylethyl (2.5-10%). Photoluminescent part according to any one of the preceding claims, characterized in that the activator comprises a mixture of diisocyanate hexamethylene oligomers (50-100%) and / or n-butyl acetate (0.1-20%) and / or 2-methoxy-1-methylethyl (10-25%) and / or 2-butoxyethyl acetate (2.5-10%) and / or naphtha (0.1-5%). Photoluminescent part according to any one of the preceding claims, characterized in that the photoluminescent film is deposited and / or printed on the stainless steel part having a thickness between 10 and 100 µm. Photoluminescent part according to any one of the preceding claims, characterized in that the photoluminescent film is deposited and / or printed on the stainless steel part having a thickness between 10 and 100 µm. Photoluminescent part according to any one of the preceding claims, characterized in that the photoluminescent pigments have emission intensities of the order of 0.1-0.3 cd / m ² during the first hour of emission. Photoluminescent part according to any one of the preceding claims, characterized in that the excitation of photoluminescent pigments may be effected by sunlight and / or ambient light. Photoluminescent part according to any one of the preceding claims, characterized in that the excitation of photoluminescent pigments is carried out using light sources with on / off cycles at intervals comprising near ultraviolet radiation. Photoluminescent part according to any one of the preceding claims, characterized in that the excitation of photoluminescent pigments is made using additional electromagnetic filters. A process for obtaining a photoluminescent part as described in any one of the preceding claims, characterized in that it comprises the following steps: Photoluminescent part according to any one of the preceding claims, characterized in that the photoluminescent pigments have emission intensities of the order of 0.1-0.3 cd / m ² during the first hour of emission. Photoluminescent part according to any one of the preceding claims, characterized in that the excitation of photoluminescent pigments may be effected by sunlight and / or ambient light. Photoluminescent part according to any one of the preceding claims, characterized in that the excitation of photoluminescent pigments is performed using light sources with on / off cycles at intervals comprising near ultraviolet radiation. Photoluminescent part according to any one of the preceding claims, characterized in that the excitation of photoluminescent pigments is made using additional electromagnetic filters. A process for obtaining a photoluminescent part as described in any one of the preceding claims, characterized in that it comprises the following steps: Preparation of mixtures of polymeric / acrylic material and photoluminescent pigments for depositing and / or printing; Deposition / printing of the mixture using spray technology with a distance of between 10 mm and 250 mm; Preparation of mixtures of polymeric / acrylic material and photoluminescent pigments for depositing and / or printing; Deposition / printing of the mixture using spray technology with a distance of between 10 mm and 250 mm; Thermally cured photoluminescent film through a temperature gradient between 40 and 80 ° C for 40 to 90 minutes. Use of a photoluminescent part as described in any one of claims 1 to 21, characterized in that it is used in the bottom / side of swimming pools, building covers, wall and floor tapestries, bathroom and kitchen walls, paintings and works. of art, furniture, lighting parts. Lisbon, December 29, 2016. Thermally cured photoluminescent film through a temperature gradient between 40 and 80 ° C for 40 to 90 minutes. Use of a photoluminescent part as described in any one of claims 1 to 21, characterized in that it is used in the bottom / side of swimming pools, building covers, wall and floor tapestries, bathroom and kitchen walls, paintings and works. of art, furniture, lighting parts. Lisbon, April 20, 2015