A pipe temperature adjusting system includes: a liquid conducting pipe; a heat-insulating cover covering the liquid conducting pipe in such a manner as to define a cylindrical space between the heat-insulating cover and the liquid conducting pipe; a heat exchange flow path disposed in the cylindrical space and along the liquid conducting pipe and allowing a heat exchange medium to flow through the heat exchange flow path; and a pump configured to supply the heat exchange medium into the heat exchange flow path. Covering the liquid conducting pipe with the cylindrical space and causing the heat exchange medium to flow through the heat exchange flow path in the cylindrical space adjusts the internal temperature of the cylindrical space to thereby adjust the temperature of the liquid conducting pipe.

A thermostat includes: a controller adapted to control the function of an associated HVAC system; and user controls adapted to provide instructions to the controller including selecting between heating functions and cooling functions, wherein the controller is limited by a maximum temperature when heating functions are selected and limited by a minimum temperature when the cooling functions are selected, wherein the maximum temperature is a lower temperature than the minimum temperature.

This disclosure relates to technologies for a sensor network, machine-to-machine (M2M) communication, machine type communication (MTC), and Internet of Things (IoT). This disclosure can be utilized in intelligent services based on the above technologies, such as smart homes, smart buildings, smart cities, smart cars or connected cars, health care, digital education, retail sales, security and safety related services, etc. This disclosure relates to a method for generating an instruction for controlling equipment on the basis of biometric information, comprising: a step of obtaining at least one biometric information; a step of determining whether to calculate a calorific value by using stored biometric information and the obtained biometric information, and calculating the calorific value by using the stored biometric information and the obtained biometric information according to the determined result; and generating an instruction for controlling the equipment on the basis of the calculated calorific value.

This disclosure relates to technologies for a sensor network, machine-to-machine (M2M) communication, machine type communication (MTC), and Internet of Things (IoT). This disclosure can be utilized in intelligent services based on the above technologies, such as smart homes, smart buildings, smart cities, smart cars or connected cars, health care, digital education, retail sales, security and safety related services, etc. This disclosure relates to a method for generating an instruction for controlling equipment on the basis of biometric information, comprising: a step of obtaining at least one biometric information; a step of determining whether to calculate a calorific value by using stored biometric information and the obtained biometric information, and calculating the calorific value by using the stored biometric information and the obtained biometric information according to the determined result; and generating an instruction for controlling the equipment on the basis of the calculated calorific value.

A vehicle seat includes a seat portion having a heating element, such as an electrically conductive wire. A sensing structure having a characteristic that is responsive to a temperature of the heating element is provided adjacent to the heating element, such as by being helically wrapped thereabout or extending parallel thereto. For example, the sensing structure may include an optical fiber, and the characteristic of the sensing structure may be an amount of light transmitted through the optical fiber. A controller is responsive to the characteristic of the sensing structure for determining when the temperature of the heating element exceeds a predetermined value.

A temperature test apparatus 1 includes a test antenna 6 configured to transmit or receive a radio signal to or from the antennas 110 in order to measure reception characteristics or transmission characteristics of the DUT 100, a heat-insulating housing 70 made of heat-insulating material surrounding a space region 71 including a quiet zone QZ, and a measuring device 20 configured to measure the transmission characteristics or the reception characteristics of the DUT 100. The heat-insulating housing 70 has a flat plate shaped part 70a in a region through which radio waves of a radio signal transmitted from the test antenna 6 passes before entering the quiet zone QZ. The flat plate shaped part 70a is perpendicular to the traveling direction of the radio waves of the radio signal entering the quiet zone QZ.

A temperature test apparatus 1 includes a test antenna 6 configured to transmit or receive a radio signal to or from the antennas 110 in order to measure reception characteristics or transmission characteristics of the DUT 100, a heat-insulating housing 70 made of heat-insulating material surrounding a space region 71 including a quiet zone QZ, and a measuring device 20 configured to measure the transmission characteristics or the reception characteristics of the DUT 100. The heat-insulating housing 70 has a flat plate shaped part 70a in a region through which radio waves of a radio signal transmitted from the test antenna 6 passes before entering the quiet zone QZ. The flat plate shaped part 70a is perpendicular to the traveling direction of the radio waves of the radio signal entering the quiet zone QZ.

There is provided a method of controlling an aerosol-generating system including an aerosol-generating device including a cavity to receive an aerosol-forming substrate, an inductive heating arrangement including an inductive heating element including a susceptor heatable by penetration with a varying magnetic field to heat the substrate, first and second inductor coils, and a power supply; the method including initiating heating of the substrate in the cavity by a first varying current in the first coil to generate a first varying magnetic field that heats a first portion of the element, and controlling the first current to increase a temperature of the first portion with a first profile; and subsequently driving a second varying current in the second coil to generate a second varying magnetic field that heats a second portion of the element, and controlling the second current to increase a temperature of the second portion with a second profile.

A thermostatic valve includes a hollow body, two openings opening into the body and being hydraulically connected by a pass section, and a shut-off component arranged partially in the pass section and having a thermostatic actuator, a return component, a valve capable of opening the first opening when actuated by the thermostatic actuator and of closing the first opening when returned by the return component. The thermostatic actuator includes a cylinder containing an expansion material and a stem defining an axial direction. A relative movement between the cylinder and the stem along the axial direction occurs under the action of the expansion material. The stem bears at an ends against an abutment element, which is movable under the action of movement component in the direction of the cylinder to allow the opening of the first opening when the temperature of the expansion material is below the threshold temperature.

The present invention provides a method of treating a substrate, the method including: performing a first heating process of heat-treating the substrate formed with a film, and a second heating process of heat-treating the substrate after the first heating process is performed; a collection operation of collecting temperature data of a first heating plate which heats the substrate in the first heating process; and a first control operation of adjusting a temperature of a second heating plate which heats the substrate in the second heating process based on the temperature data.