Provided is an application method including: a feeding step including feeding a viscous material to a discharge member; a temperature measurement step including measuring a temperature of the viscous material in a flow path through which the viscous material is fed to the discharge member; a pressurizing step including pressurizing the viscous material fed to the discharge member, based on the temperature measured in the temperature measurement step; and a discharge step including discharging, through the discharge member, the viscous material pressurized in the pressurizing step.

Provided is an application method including: a feeding step including feeding a viscous material to a discharge member; a temperature measurement step including measuring a temperature of the viscous material in a flow path through which the viscous material is fed to the discharge member; a pressurizing step including pressurizing the viscous material fed to the discharge member, based on the temperature measured in the temperature measurement step; and a discharge step including discharging, through the discharge member, the viscous material pressurized in the pressurizing step.

Controlling application of adhesive on a substrate includes using a gas sensor, obtaining a first sensor signal. The first sensor signal indicates a partial pressure of a gas that arises from a constituent of the adhesive. Based at least in part on this partial pressure, the controller either controls an applicator's delivery of the adhesive to a substrate or causes an error signal indicative of the adhesive's unsuitability for adhesion.

Systems and methods for controlling the temperature of liquid coatings discharged from air pressurized spray pots and the like are described. The non-electrical temperature-controlled systems rely on the pressurization and expansion of air and/or other gases to lower or increase the temperature of the sprayed liquid coating. The system includes cooling coils surrounding a pressurized spray pot contained within an insulated enclosure. Pressurized ambient air is passed through a cooling vortex cylinder before passing into the cooling coils. The cooled air preferably then passes into an insulated envelope surrounding the discharge lines to the spray gun. An optional system structure adds a second cooling vortex cylinder to reduce the temperature of the pressurized air in a second flow line that serves to pressurize the spray pot and to pass to the spray gun parallel to the cooled liquid line.

Systems and methods for controlling the temperature of liquid coatings discharged from air pressurized spray pots and the like are described. The non-electrical temperature-controlled systems rely on the pressurization and expansion of air and/or other gases to lower or increase the temperature of the sprayed liquid coating. The system includes cooling coils surrounding a pressurized spray pot contained within an insulated enclosure. Pressurized ambient air is passed through a cooling vortex cylinder before passing into the cooling coils. The cooled air preferably then passes into an insulated envelope surrounding the discharge lines to the spray gun. An optional system structure adds a second cooling vortex cylinder to reduce the temperature of the pressurized air in a second flow line that serves to pressurize the spray pot and to pass to the spray gun parallel to the cooled liquid line.

A shower head water collecting device includes a water collecting hanging component, a temperature sensing element, an assembling component, a solar panel, and a temperature displaying element. The water collecting hanging component is provided for a shower head to be hung thereon and collects the water spraying from the shower head. The temperature sensing element is disposed inside the water collecting hanging component to sense the temperature of water spraying from the shower head. The assembling component is mounted on top of the water collecting hanging component. The solar panel and the temperature displaying element are disposed in the assembling component. The solar panel is electrically connected to the temperature sensing element and the temperature displaying element, wherein the solar panel harvests the light energy from the outside and converts it into electrical energy to supply power to the temperature sensing element and the temperature displaying element.

A smart shower head to regulate temperature of water being supplied is disclosed. The smart shower head comprises a showering section (101) for showering water, a shower head arm connecting the showering section (101) and supplying water to the showering section (101), and at least one compartmentalized nero-thermal coil 103 running through the length of the shower head arm (102) and the showering section (101).

A cooling system for the decoating system includes a sensor, a control device, and a controller communicatively coupled with the sensor and the control device. The sensor is configured to measure a characteristic of the cooling system in the decoating system, the control device controls the characteristic of the cooling system, and the controller is configured to adjust the control device to adjust the characteristic of the cooling system based on at least one of a measured temperature within the decoating system or the measured characteristic. A method of controlling a temperature of the decoating system includes measuring a temperature within a piece of equipment of the decoating system and measuring a characteristic the cooling system in the piece of equipment of the decoating system. The method includes controlling the cooling system to adjust the characteristic based on at least one of the measured temperature or the measured characteristic.

A cooling system for the decoating system includes a sensor, a control device, and a controller communicatively coupled with the sensor and the control device. The sensor is configured to measure a characteristic of the cooling system in the decoating system, the control device controls the characteristic of the cooling system, and the controller is configured to adjust the control device to adjust the characteristic of the cooling system based on at least one of a measured temperature within the decoating system or the measured characteristic. A method of controlling a temperature of the decoating system includes measuring a temperature within a piece of equipment of the decoating system and measuring a characteristic the cooling system in the piece of equipment of the decoating system. The method includes controlling the cooling system to adjust the characteristic based on at least one of the measured temperature or the measured characteristic.

Embodiments described herein generally related to a substrate processing apparatus, and more specifically to an improved showerhead assembly for a substrate processing apparatus. The showerhead assembly includes a chill plate, a gas plate, and a gas distribution plate having a top surface and a bottom surface. A plurality of protruded features contacts the top surface of the gas distribution plate. A fastener and an energy storage structure is provided on the protruded features. The energy storage structure is compressed by the fastener and axially loads at least one of the protruded features to compress the chill plate, the gas plate and the gas distribution plate.