A furnace monitoring system for monitoring a furnace over a span of time during furnace operation, including a thermal imaging apparatus, the apparatus is disposed outside of the furnace and at a distance from the exterior of the furnace to generate field signals of the furnace; a signal processing unit configured and programmed for receiving the field signals and generating a temperature map of the exterior of the furnace; and a means for displaying the temperature map locally or remotely. Wherein in that the furnace monitoring system is a system for monitoring the furnace over a span of time during furnace operation and in that the generated temperature map is divided into several zones, which correspond to different components of the furnace selected from burner, viewing port for burner observation, charging port, discharging port and flue gas channel.

A system for monitoring brick in a rotary kiln includes an infrared sensor and a computing system configured to: obtain a digital model of a brick layer of a rotary kiln having a plurality of bricks, wherein the digital model of the brick layer is based on a measured brick thickness correlated with a measured infrared temperature for each brick; obtain infrared data of the rotary kiln with the at least one infrared imaging sensor; determine the measured infrared temperature for each brick; determine a brick thickness of a first brick in the brick layer of the rotary kiln based on the measured infrared temperature assigned to the first brick with the digital model of the brick layer; and provide the brick thickness of the first brick in a brick thickness report.

A stove guard having a data processing unit and a heat sensor arrangement for receiving heat radiation from objects located in a given field of view and for delivering the detector signals indicative of the received heat radiation to the data processing unit. The heat sensor arrangement is arranged to generate detector signals differently corresponding to the heat radiation received from a central area of the field of view than to the heat radiation received from a circumferential area of the field of view.

According to an aspect of the present invention, there is provided a deposition apparatus including: a reaction space which is a reaction chamber; a front chamber for deposition; a raw material supply port that is configured to supply a raw material to the reaction space; an opening for measuring a temperature of a wafer mounted on a wafer mounting surface of a mounting stage disposed in the reaction space; and a partition plate that partitions the reaction space and the front chamber for deposition, in which the raw material supply port is positioned on the same plane as the partition plate or on the reaction space side from the partition plate, and the opening is positioned in the front chamber for deposition side from the partition plate.

A method of recording images within a furnace using a thermal imaging camera comprising a bore scope connected to a digital camera unit is described, comprising the steps of: (a) inserting the borescope into the interior of the furnace, (b) collecting one of more images of the interior of the furnace using the thermal imaging camera with the borescope at a first position, and (c) moving the borescope from the first position to a second position and collecting one or more images of the interior of the furnace as the borescope is moved from the first position to the second position, wherein the borescope movement is guided by means of a guide device comprising a movable borescope mounting, mounted externally on the furnace.

A top hood for covering food in a microwave oven is provided. The top hood (H1) includes a microwave transparent wall structure including a side wall (SW) and top part (TP). The side wall (SW) and top part (TP) define the internal area (IA) covered by the top hood (H1). Attached to the wall structure of the top hood (H1), the top hood (H1) includes a temperature sensor (TS) for measuring the temperature within the internal area (IA) covered by the top hood (H1). The top hood further includes a wireless transmitter (WT) for transmitting the measured temperature information to an external display unit (DU).

The invention relates to an immersion device and a method for detecting a position of an optical cored wire using an immersion device. An immersion device for measuring a temperature of a metal melt inside an electric arc furnace vessel with an optical cored wire comprises a blowing lance for blowing purge gas into an entry point to the vessel and a detecting means for detecting a position of the optical cored wire. The optical cored wire can be moved in a feeding channel and/or in the blowing lance relative to the entry point. The detecting means is configured to detect the presence of the optical cored wire in or close to the blowing lance. This enables short distances between the leading end of the fiber and the melt and, thus, short time intervals between temperature measurement sequences.

A temperature monitoring system includes an access port configured to mount to an inspection window of a process heater that includes heating tubulars mounted in an inner volume of the process heater, the access port including at least one visual access portion configured to provide visual access to at least a portion of the heating tubulars; a flange assembly including a bore that extends from a first side configured to mount to the access port to a second side; and a thermal imaging system configured to mount to the second side of the flange assembly, the thermal imaging system including at least one thermal image capture device including a field of view through the bore of the flange of assembly and the at least one visual access portion and into the inner volume of the process heater to capture at least one image of radiation emitted from the heating tubulars.

A heat treatment monitoring system comprises a sensor unit having at least one sensor to determine current sensor data of food being heated; a processing unit to determine current feature data from the current sensor data; and a monitoring unit adapted to determine a current heating process state in a current heating process of the monitored food by comparing the current feature data with reference feature data of a reference heating process.

A temperature monitoring system for a substrate heating furnace includes a temperature monitor, and the temperature monitor is located on a prong of a mechanical arm which is configured to fetch and place a substrate. The temperature monitor is configured to monitor the temperature of the substrate which has been heated by the substrate heating furnace and is located on the prong.