A wireless energy transmitting apparatus includes: a direction-finding and location device configured to determine a position of an energy receiving apparatus based on beacon information of the energy receiving apparatus; an energy generation device configured to generate energy, convert the energy into high-frequency electromagnetic waves having a frequency higher than a predetermined frequency threshold, and transmit the high-frequency electromagnetic waves to the energy receiving apparatus; and a processor configured to control the energy generation device to transmit the high-frequency electromagnetic waves to the energy receiving apparatus based on the position of the energy receiving apparatus. The position of the energy receiving end is determined based on the direction-finding and location device, and the energy generation device is controlled to convert the energy into high-frequency electromagnetic waves having a frequency higher than a predetermined frequency and transmit the same to the energy receiving end.

An apparatus for processing substrates includes a continuum radiation source, a source manifold optically coupled to the continuum radiation source and comprising: a plurality of beam guides, each having a first end that optically couples the beam guide to the continuum radiation source; and a second end. The apparatus also includes a detector manifold to detect radiation originating from the source manifold and transmitted through a processing area, and one or more transmission pyrometers configured to analyze the source radiation and the transmitted radiation to determine an inferred temperature proximate the processing area.

A system for detecting an hotspots can include: at least one infrared imaging sensor; and an imaging analysis computer operably coupled with the at least one infrared imaging sensor. The imaging analysis computer can be configured to control any infrared imaging sensor and acquire infrared images therefrom at any rate and in any duration. The imaging analysis computer can be configured to analyze the infrared images in order to detect temperatures and identify hotspots. The temperature and hotspot information can be used to control a cooling system that can spray water on and around hotspots for temperature control.

A multifunctional protective isolation mask is provided, comprising a mask main body (1) and a wearing monitoring mechanism. The wearing monitoring mechanism comprises a temperature sensor (4), a controller (5), a display screen (6) and a first press button (7). After a user wears the mask, the temperature sensor (4) collects corresponding temperature information and transmits the temperature information to the controller (5), and at the same time, the first press button (7) is pressed and transmits an electric signal to the controller (5); when the controller (5) determines that the temperature information belongs to the human body temperature range and receives the electric signal sent by the first press button (7), it is determined that the user is wearing the mask, and the wearing time is thus recorded, and after the user takes off the mask, the first press button (7) resets.

A system for determining occupancy in an environment is provided. The system includes plurality of sensor bundles, with each bundle including a presence sensor and a motion sensor. The system further includes a controller in communication with each sensor bundle. The controller is configured to designate one of the sensor bundles as presence triggered if persons are present within a field of view of the presence sensor. The controller is further configured to designate one of the sensor bundles as motion triggered if persons are moving within a field of view of the motion sensor. The controller is further configured to determine a triggered bundle count of the sensor bundles which are both presence triggered and motion triggered. The controller is further configured to determine an occupancy count for the environment based upon the triggered bundle count.

Even a radiation thermometer using a quantum infrared sensor appropriately measures the temperature of a substrate irradiated with a flash of light. A heat treatment apparatus includes a quantum infrared sensor configured to measure a temperature of the first substrate and a temperature of the second substrate. The heat treatment apparatus further includes a temperature correction unit configured to correct, using a correction coefficient calculated based on the reference temperature and the shift temperature, a temperature of the second substrate on which second heat treatment having irradiation with the flash of light is performed, the temperature being measured by the quantum infrared sensor.

A system and method for monitoring a device includes a temperature sensor, a processing unit, and an output unit. The temperature sensor acquires a temperature measurement during a heat-up phase of a component and provides a temperature measurement to the processing unit, which selects a simulated transient temperature distribution of the simulated component of the simulated device from a plurality of simulated transient temperature distributions of the simulated component of the simulated device. The selection comprises a comparison of the at least one temperature measurement with the plurality of simulated transient temperature distributions at an equivalent time point in the simulated heat-up to a time point at which the temperature measurement was acquired. When a hot spot is developing an output unit outputs an indication of a fault associated with the component.

A cigarette temperature detection device including multiple cylindrical convex lenses is provided, wherein each of the cylindrical convex lenses has a thicker central wall between two thinner end walls formed by rotating a parallel line at a predetermined distance around a long axis of an elliptical-like section resulting from cutting the circular convex lens by a plane perpendicular to a centerline. The disclosed cigarette temperature detection device allows accurate and reliable detection of a temperature of an entire circumferential surface of a cigarette on site.

A rotary animal repelling device, including: a housing, which includes a fixed body part and a head above the body part, and a mounting disc is fixedly provided on an inner periphery of a cavity of the head. A motor is located on the mounting disc, a rotating shaft extends through the mounting disc and is fixed to a side of the body part facing the head. The mounting disc has a sounder and a laser light, and the sounder and the laser light are coupled to the motor by transmission line, respectively. The laser light extends to outside of the head, the mounting disc has a radar sensor to detect an approach of animals and a control main board communicatively coupled to the radar sensor, the control main board is communicatively coupled to the motor, and the control main board has a control switch extending outside of the housing.

A measurement device includes a base, a platform, a temperature sensor, and a weighing component. The platform is movably disposed on the base. The temperature sensor is disposed on the base or the platform. The weighing component is accommodated in the base. The platform has a weight-measuring area and a temperature-measuring area which is located within the weight-measuring area and corresponding to the temperature sensor.