A hybrid compound for insulating a substrate is formed by dispersing functionalized inorganic nanomaterials in a non-toxic reagent at a controlled pH using volatile bases to form an aqueous dispersion. The aqueous dispersion is then stirred to form the hybrid compound. The compound is then applied to a substrate and dried to from an insulating layer. The insulating layer protects the substrate from temperatures exceeding 1200 degrees Fahrenheit.
b, and seismic vibration detection means 80 installed on the outer body 20. These components are integrated into an air-circulating electric roaster 10 and a control box 90 designed to inform about the operational status of the electric roaster.
New and innovative compositions of matter for providing thermally insulative coating in a variety of applications are disclosed. The insulative coating can be applied to any suitable structure for which insulation is beneficial. The provided insulative coating has a low thermal conductivity and high emissivity which contribute to the insulative coating's desirable insulative properties. The insulative coating also demonstrates its advantageous insulating effect (i.e. low thermal conductivity) over a wide range of temperatures and adds minimal thickness to the structures on which it is applied while still providing equivalent or better insulative properties as other, thicker insulating materials.
C04B 26/10 - Composés macromoléculaires obtenus autrement que par des réactions faisant intervenir uniquement des liaisons non saturées carbone-carbone
A new and innovative fireproof coating is provided. The fireproof coating exhibits high heat insulation combined with a low flame spread and low smoke density. The fireproof coating can be applied to any suitable structure for which fireproofing is beneficial. An advantage of the fireproof coating is low weight and high flexibility compared to conventional fireproofing technologies while still providing equivalent or better fireproofing properties. The provided fireproof coating has a low thermal conductivity and high emissivity, each of which provide the coating with desirable fireproofing properties. The fireproof coating also demonstrates its advantageous fireproofing properties over a wide range of temperatures and adds minimal thickness to the structures on which it is applied while still providing equivalent or better fireproofing properties as other, thicker fireproof materials.
C04B 26/10 - Composés macromoléculaires obtenus autrement que par des réactions faisant intervenir uniquement des liaisons non saturées carbone-carbone
Compositions of matter for use as a roof coating are provided. The roof coating can be applied to any suitable roof of any building. When applied to a roof, the roof coating insulates the building's interior from some of the sun's thermal energy, which would otherwise radiate into the building and raise the interior temperature. The roof coating can therefore reduce energy consumption involved in cooling the building's interior. The roof coating demonstrates advantageous thermal insulation properties (e.g., low thermal conductivity) over a wide range of temperatures and when applied with minimal thickness. The provided roof coating demonstrates high reflectance, high emissivity, low thermal conductivity, low flame spread, high solar reflectance index (SRI) in the range of 100 to 120, and acts as a sealer and waterproofer, which all contribute to its desirable properties for use as a thermally insulating roof coating.
C04B 26/10 - Composés macromoléculaires obtenus autrement que par des réactions faisant intervenir uniquement des liaisons non saturées carbone-carbone
A vehicle coating to thermally insulate the vehicle's interior is provided. The vehicle coating may be applied to the exterior (e.g., roof) of any suitable moving vehicle, such as a bus, RV, delivery truck, construction vehicle (e.g., cement mixer), train car. When applied to a vehicle's exterior, the vehicle coating provides the benefit of insulating the vehicle's interior from some of the sun's thermal energy, which would otherwise radiate into the vehicle and increase the interior temperature. The vehicle coating demonstrates advantageous thermal insulation properties (e.g., low thermal conductivity) over a wide range of temperatures and when applied with minimal thickness. The provided vehicle coating demonstrates high reflectance, high emissivity, low thermal conductivity, and high solar reflectance index (SRI), and is suitable for high vibration high uplift winds, which all contribute to its desirable properties for use as a thermally insulating vehicle coating.
C04B 26/10 - Composés macromoléculaires obtenus autrement que par des réactions faisant intervenir uniquement des liaisons non saturées carbone-carbone
A new and innovative hard ceramic coating having refractory properties is provided. The ceramic coating may be used as a replacement for refractory materials. As opposed to polymer-based coatings that are sacrificial when exposed to extreme temperatures, the ceramic coating is a non-sacrificial, fully inorganic (e.g., free of organic components) coating that resists many thermal cycles. The ceramic coating is also thinner and lighter than conventional refractory materials the ceramic coating can replace. The ceramic coating demonstrates advantageous thermal insulation properties (e.g., low thermal conductivity) over a wide range of temperatures and when applied with minimal thickness. The ceramic coating also demonstrates high emissivity, low thermal conductivity, and high resistance mechanical properties, which are all desirable properties for use as a thermally insulating replacement coating for refractory materials.
C04B 35/66 - Réfractaires monolithiques ou mortiers réfractaires, y compris ceux contenant de l'argile
C04B 35/14 - Produits céramiques mis en forme, caractérisés par leur compositionCompositions céramiquesTraitement de poudres de composés inorganiques préalablement à la fabrication de produits céramiques à base d'oxydes à base de silice
C04B 35/622 - Procédés de mise en formeTraitement de poudres de composés inorganiques préalablement à la fabrication de produits céramiques
C04B 35/80 - Fibres, filaments, "whiskers", paillettes ou analogues
A new and innovative fireproof coating is provided. The fireproof coating exhibits high heat insulation combined with a low flame spread and low smoke density. The fireproof coating can be applied to any suitable structure for which fireproofing is beneficial. An advantage of the fireproof coating is low weight and high flexibility compared to conventional fireproofing technologies while still providing equivalent or better fireproofing properties. The provided fireproof coating has a low thermal conductivity and high emissivity, each of which provide the coating with desirable fireproofing properties. The fireproof coating also demonstrates its advantageous fireproofing properties over a wide range of temperatures and adds minimal thickness to the structures on which it is applied while still providing equivalent or better fireproofing properties as other, thicker fireproof materials.
Compositions of matter for use as a roof coating are provided. The roof coating can be applied to any suitable roof of any building. When applied to a roof, the roof coating insulates the building's interior from some of the sun's thermal energy, which would otherwise radiate into the building and raise the interior temperature. The roof coating can therefore reduce energy consumption involved in cooling the building's interior. The roof coating demonstrates advantageous thermal insulation properties (e.g., low thermal conductivity) over a wide range of temperatures and when applied with minimal thickness. The provided roof coating demonstrates high reflectance, high emissivity, low thermal conductivity, low flame spread, high solar reflectance index (SRI) in the range of 100 to 120, and acts as a sealer and waterproofer, which all contribute to its desirable properties for use as a thermally insulating roof coating.
New and innovative compositions of matter for providing thermally insulative coating in a variety of applications are disclosed. The insulative coating can be applied to any suitable structure for which insulation is beneficial. The provided insulative coating has a low thermal conductivity and high emissivity which contribute to the insulative coating's desirable insulative properties. The insulative coating also demonstrates its advantageous insulating effect (i.e. low thermal conductivity) over a wide range of temperatures and adds minimal thickness to the structures on which it is applied while still providing equivalent or better insulative properties as other, thicker insulating materials.
A vehicle coating to thermally insulate the vehicle's interior is provided. The vehicle coating may be applied to the exterior (e.g., roof) of any suitable moving vehicle, such as a bus, RV, delivery truck, construction vehicle (e.g., cement mixer), train car. When applied to a vehicle's exterior, the vehicle coating provides the benefit of insulating the vehicle's interior from some of the sun's thermal energy, which would otherwise radiate into the vehicle and increase the interior temperature. The vehicle coating demonstrates advantageous thermal insulation properties (e.g., low thermal conductivity) over a wide range of temperatures and when applied with minimal thickness. The provided vehicle coating demonstrates high reflectance, high emissivity, low thermal conductivity, and high solar reflectance index (SRI), and is suitable for high vibration high uplift winds, which all contribute to its desirable properties for use as a thermally insulating vehicle coating.
A new and innovative hard ceramic coating having refractory properties is provided. The ceramic coating may be used as a replacement for refractory materials. As opposed to polymer-based coatings that are sacrificial when exposed to extreme temperatures, the ceramic coating is a non-sacrificial, fully inorganic (e.g., free of organic components) coating that resists many thermal cycles. The ceramic coating is also thinner and lighter than conventional refractory materials the ceramic coating can replace. The ceramic coating demonstrates advantageous thermal insulation properties (e.g., low thermal conductivity) over a wide range of temperatures and when applied with minimal thickness. The ceramic coating also demonstrates high emissivity, low thermal conductivity, and high resistance mechanical properties, which are all desirable properties for use as a thermally insulating replacement coating for refractory materials.
Compositions of matter for coating a solar panel are provided to increase the solar panel's efficiency. The solar panel coating may be applied to the outermost transparent layer of the solar panel that is exposed to the ambient environment, or in some instances, may be integrated with the outermost transparent layer. The solar panel coating allows enough light to pass through and reach the solar cells while also reducing heat transfer to the solar panel, thereby slowing the rate at which the solar panel heats up. The solar panel coating reduces heat transfer and promotes cooling of the solar panel at least in part by increasing emissivity of the solar panel's surface. The solar panel coating therefore elevates the solar panel's performance while adding minimal thickness to the solar panel.
An air circulation roaster for tables with a safety function enabled to remove foreign substances (oil and nitrogen dioxide) generated during cooking of meat, reducing contamination of the air around the roaster, has a safety function that cuts off power pending the sensed temperature of the roast plate. The air circulation roaster has a temperature sensor detecting the temperature of the roast plate, a control box placed outside the body when the temperature cuts off power supplied to the heating lamp when the heating unit exceeds the set limit. A platinum catalyst filter placed around the outside of the heating unit is coated with platinum on a network-shaped ceramic.
A hybrid compound for insulating a substrate is formed by dispersing functionalized inorganic nanomaterials in a non-toxic reagent at a controlled pH using volatile bases to form an aqueous dispersion. The aqueous dispersion is then stirred to form the hybrid compound. The compound is then applied to a substrate and dried to from an insulating layer. The insulating layer protects the substrate from temperatures exceeding 1200 degrees Fahrenheit.
B82Y 30/00 - Nanotechnologie pour matériaux ou science des surfaces, p. ex. nanocomposites
C09D 5/00 - Compositions de revêtement, p. ex. peintures, vernis ou vernis-laques, caractérisées par leur nature physique ou par les effets produitsApprêts en pâte
C09D 7/61 - Adjuvants non macromoléculaires inorganiques
H01B 3/02 - Isolateurs ou corps isolants caractérisés par le matériau isolantEmploi de matériaux spécifiés pour leurs propriétés isolantes ou diélectriques composés principalement de substances inorganiques
18.
HYBRID INSULATING COMPOUND FOR USE IN SYSTEMS REQUIRING HIGH POWER OF THERMAL INSULATION
A hybrid compound for insulating a substrate is formed by dispersing functionalized inorganic nanomaterials in a non-toxic reagent at a controlled pH using volatile bases to form an aqueous dispersion. The aqueous dispersion is then stirred to form the hybrid compound. The compound is then applied to a substrate and dried to from an insulating layer. The insulating layer protects the substrate from temperatures exceeding 1200 degrees Fahrenheit.
C09D 7/61 - Adjuvants non macromoléculaires inorganiques
B82Y 30/00 - Nanotechnologie pour matériaux ou science des surfaces, p. ex. nanocomposites
C09D 5/00 - Compositions de revêtement, p. ex. peintures, vernis ou vernis-laques, caractérisées par leur nature physique ou par les effets produitsApprêts en pâte
H01B 3/02 - Isolateurs ou corps isolants caractérisés par le matériau isolantEmploi de matériaux spécifiés pour leurs propriétés isolantes ou diélectriques composés principalement de substances inorganiques
19.
Hybrid insulating compound for use in systems requiring high power of thermal insulation
A hybrid compound for insulating a substrate is formed by dispersing functionalized inorganic nanomaterials in a non-toxic reagent at a controlled pH using volatile bases to form an aqueous dispersion. The aqueous dispersion is then stirred to form the hybrid compound. The compound is then applied to a substrate and dried to from an insulating layer. The insulating layer protects the substrate from temperatures exceeding 1200 degrees Fahrenheit.
