The solenoid valve may include a coil, a stem core tube, and a core. The coil may include one or more electrical leads configured to provide the coil with an electric current. The coil may be configured to convert the electric current to a magnetic field. At least a portion of the stem core tube may be insertable within a coil channel. At least a portion of the core may be insertable within an end of the stem core tube and may be moveable within the stem core tube via the magnetic field. At least one of the stem core tube or the core may be fabricated from 434 stainless steel and treated with one or more corrosion prevention processes. The solenoid valve may be couplable to one or more components of the brewing apparatus. The brewing apparatus may be dimensioned to fit within a compartment of the aircraft galley.

Method of manufacturing a spectrally selective surface. The method comprises cleaning an outside of a tubular substrate, e.g. by sonicating in acetone, polishing the cleaned outside, and depositing a CoCr coating on the polished outside, i.e. the tubular substrate's outside. The CoCr coating comprises Co(II) compounds and Cr(III) compounds but no Cr(VI) compounds. By applying a DES electrolyte Cr(III)-ions may be solved in the electrolyte such that a receiver tube arranged in the electrolyte may become coated with a selective CoCr coating from Cr(III)-ions, where the optical characteristics regarding absorptance and emittance for the resulting receiver tube are comparable or surpasses traditional black chrome. Thereby use of harmful hexavalent chrome could be avoided, which may achieve more healthy and environmental friendly conditions. Particularly, no harmful Cr(VI)-ions or rest substances comprising them will contaminate ambient air or need to be handled or disposed.

Method of manufacturing a spectrally selective surface. The method comprises cleaning an outside of a tubular substrate, e.g. by sonicating in acetone, polishing the cleaned outside, and depositing a CoCr coating on the polished outside, i.e. the tubular substrate's outside. The CoCr coating comprises Co(II) compounds and Cr(III) compounds but no Cr(VI) compounds. By applying a DES electrolyte Cr(III)-ions may be solved in the electrolyte such that a receiver tube arranged in the electrolyte may become coated with a selective CoCr coating from Cr(III)-ions, where the optical characteristics regarding absorptance and emittance for the resulting receiver tube are comparable or surpasses traditional black chrome. Thereby use of harmful hexavalent chrome could be avoided, which may achieve more healthy and environmental friendly conditions. Particularly, no harmful Cr(VI)-ions or rest substances comprising them will contaminate ambient air or need to be handled or disposed.

Manufacturing methods are disclosed that can electropolish a metal surface by disposing an electrode over the metal surface, and a permeable dielectric spacer between the metal surface and the electrode. An electrolyte is infiltrated into the permeable dielectric spacer, and an electrical voltage differential is applied to the electrode and the metal surface.

Manufacturing methods are disclosed that can electropolish a metal surface by disposing an electrode over the metal surface, and a permeable dielectric spacer between the metal surface and the electrode. An electrolyte is infiltrated into the permeable dielectric spacer, and an electrical voltage differential is applied to the electrode and the metal surface.

An electric kettle may include a body made of stainless steel and having a cylindrical shape with an open upper surface and an open lower surface, a heating module configured to form a bottom of a space in which fluid, such as water is contained inside of the body and heat the fluid, a handle that protrudes from an upper portion of an outer surface of the body, and a base configured to support the body at a lower side and supply power to the heating module in a state in which the body is seated. The body may include an outer body configured to form the outer surface of the body, an inner body connected to the outer body inside of the outer body and configured to form a space in which fluid is contained, a heat insulation space between the outer body and the inner body, and at least one body hole opened in the lower surface of the body and configured to communicate with the heat insulation space.

The disclosure relates to the use of H.sub.2SO.sub.4 as an electrolyte in processes for polishing metals, specifically metal parts, for example in jewellery. According to some embodiments the polishing is carried out based on ion transport with electrically conductive free solids in a gaseous environment. According to some embodiments the solids comprise spherical particles with porosity and affinity for retaining the electrolyte so that they have appreciable electric conductivity.

A laminate for a see-through electrode includes a transparent base and a metal layer that is provided on at least one of both surfaces of the transparent base. The metal layer has a first surface and a second surface, the first surface facing the transparent base, the second surface being at a side opposite to the first surface. And the second surface has a kurtosis (Rku) ranging from 1.00 to 3.10, inclusive.

A laminate for a see-through electrode includes a transparent base and a metal layer that is provided on at least one of both surfaces of the transparent base. The metal layer has a first surface and a second surface, the first surface facing the transparent base, the second surface being at a side opposite to the first surface. And the second surface has a kurtosis (Rku) ranging from 1.00 to 3.10, inclusive.

A method for electropolishing a manufactured metallic article, the method comprising: contacting the metallic article with an electropolishing electrolyte; and electropolishing the metallic article in the electropolishing electrolyte through the application of an applied current regime comprising: at least one electropolishing regime, each electropolishing regime comprising a current density of at least 2 A/cm.sup.2 and a voltage comprising a shaped waveform having a frequency from 2 Hz to 300 kHz, a minimum voltage of at least 0 V and a maximum voltage of between 0.5 to 500 V.