A self-watering portable greenhouse is disclosed having a tubular frame constructed of light-weight, water-tight tubular members which serves as a combined structural skeleton for external walls, a platform for plant containers, and a reservoir for liquid nutrients provided to plants in plant containers by self-watering through a wick connecting the reservoir and the plant containers.

A luminescent layer is described comprising an Eu.sup.2+ doped inorganic luminescent material comprising or consisting essentially of the elements Al and/or Si and the elements O and/or N, the doped inorganic luminescent material converting radiation of the UV region between 200 nm and 400 nm of the solar spectrum into the photosynthetically active radiation (PAR) region (400 nm-700 nm) of the solar spectrum, wherein the Si concentration in the inorganic luminescent material is selected between 0 and 45 at. %, the Al concentration between 0 and 50 at. %, the O concentration between 0 and 70 at. %, the N concentration between 0 and 60 at. % and the Eu2+ between 0.01 and 30 at. %.

Luminescent greenhouse glazing structures are described wherein the glazing structures comprise: a glass pane for a greenhouse; and, one or more Eu.sup.2+ doped amorphous inorganic luminescent thin film layers provided over the glass pane, wherein the one or more Eu.sup.2+ doped amorphous inorganic luminescent layers comprise or consist essentially of the elements Al and/or Si and the elements O and/or N; and, wherein the Si concentration is selected between 0 and 45 at. %, the Al concentration between 0 and 50 at. %, the O concentration between 0 and 70 at. %, the N concentration between 0 and 60 at. % and the Eu.sup.2+ between 0.01 and 30 at. %.

The invention relates to biaxially oriented, UV-stabilized polyester films incorporating silicon dioxide particles as light-scattering particles and a UV stabilizer; a process for producing the same and to use thereof in greenhouse blinds. The invention particularly relates to single- or multilayer polyester film with transparency from 70 to 92 %, where: the film includes at least 1.0% by weight to at most 2.5% by weight of SiO.sub.2, with the d.sub.50 value of these SiO.sub.2 particles ranging from 3 to 9 μm, the SV value of the film is at least 700, the scattering factor SF of the film is at least 2 and not more than 8, the haze of the film is from 60 to 95%, and the clarity of the film is from 15 to 40%; and all of the external layers comprise at least 0.3 % by weight of an organic UV stabilizer.

A transparent substrate includes a texture in relief on at least one of its two main faces, such that when the substrate is textured on a single face, the average slope P.sub.m in degrees of this textured face is lower than 2, and when the substrate is textured on both its faces, the sum of the two average slopes (Pm1, Pm2) of the respective faces is lower than 3.

A self-watering portable greenhouse is disclosed having a tubular frame constructed of light-weight, water-tight tubular members which serves as a combined structural skeleton for external walls, a platform for plant containers, and a reservoir for liquid nutrients provided to plants in plant containers by self-watering through a wick connecting the reservoir and the plant containers.

A greenhouse glazing, including a glass substrate with a first surface containing a first coating and a second surface containing a second coating. The first surface is an air-side face of the glass substrate and the second surface is a tin-side face of the glass substrate, and the second surface is textured prior to a deposition of the second coating in such a way that a roughness parameter Rsm is at most 155 m. The first coating on the first surface contains a nano-porous silica layer having a thickness between 80 and 150 nm and a transparent conductive oxide located between the nano-porous silica layer and the first surface of the glass substrate. The second coating on the second surface contains a nano-porous silica layer having a thickness between 80 and 180 nm.

A luminescent layer is described comprising an Eu.sup.2+ doped inorganic luminescent material comprising or consisting essentially of the elements Al and/or Si and the elements O and/or N, the doped inorganic luminescent material converting radiation of the UV region between 200 nm and 400 nm of the solar spectrum into the photosynthetically active radiation (PAR) region (400 nm-700 nm) of the solar spectrum, wherein the Si concentration in the inorganic luminescent material is selected between 0 and 45 at. %, the Al concentration between 0 and 50 at. %, the O concentration between 0 and 70 at. %, the N concentration between 0 and 60 at. % and the Eu2+ between 0.01 and 30 at. %.

The invention relates to biaxially oriented, UV-stabilized polyester films incorporating silicon dioxide particles as light-scattering particles and a UV stabilizer; a process for producing the same and to use thereof in greenhouse blinds. The invention particularly relates to single- or multilayer polyester film with transparency from 70 to 92 %, where: the film includes at least 1.0% by weight to at most 2.5% by weight of SiO.sub.2, with the d.sub.50 value of these SiO.sub.2 particles ranging from 3 to 9 m, the SV value of the film is at least 700, the scattering factor SF of the film is at least 2 and not more than 8, the haze of the film is from 60 to 95%, and the clarity of the film is from 15 to 40%; and all of the external layers comprise at least 0.3 % by weight of an organic UV stabilizer.

Luminescent greenhouse glazing structures are described wherein the glazing structures comprise: a glass pane for a greenhouse; and, one or more Eu.sup.2+ doped amorphous inorganic luminescent thin film layers provided over the glass pane, wherein the one or more Eu.sup.2+ doped amorphous inorganic luminescent layers comprise or consist essentially of the elements Al and/or Si and the elements O and/or N; and, wherein the Si concentration is selected between 0 and 45 at. %, the Al concentration between 0 and 50 at. %, the O concentration between 0 and 70 at. %, the N concentration between 0 and 60 at. % and the Eu.sup.2+ between 0.01 and 30 at. %.