A display panel and a temperature regulation method for a display panel are provided. The display includes a substrate, a thin film transistor layer, a first passivation layer, a photoelectric detector, a first light-shielding layer, and a second light-shielding layer. The first light-shielding layer is disposed on one side of the photoelectric detector away from the substrate. The second light-shielding layer is disposed on the lateral of the photoelectric detector.

In accordance with an embodiment, an energy storage system includes energy storage container that a temperature control system, a battery cluster, and a controller. The controller determines a specified temperature of the temperature control system corresponding to a maximum difference between an available capacity of the battery cluster and a power consumption of the temperature control system as a target temperature. The determination of the specified temperature is based on: a correspondence between the available capacity of the battery cluster and a plurality of different specified temperatures in a specified temperature set of the temperature control system, and a correspondence between the power consumption of the temperature control system and the plurality of different specified temperatures in the specified temperature set of the temperature control system. The temperature control system is configured to adjust a temperature inside the energy storage container to the target temperature.

In accordance with an embodiment, an energy storage system includes energy storage container that a temperature control system, a battery cluster, and a controller. The controller determines a specified temperature of the temperature control system corresponding to a maximum difference between an available capacity of the battery cluster and a power consumption of the temperature control system as a target temperature. The determination of the specified temperature is based on: a correspondence between the available capacity of the battery cluster and a plurality of different specified temperatures in a specified temperature set of the temperature control system, and a correspondence between the power consumption of the temperature control system and the plurality of different specified temperatures in the specified temperature set of the temperature control system. The temperature control system is configured to adjust a temperature inside the energy storage container to the target temperature.

The invention relates to household appliances intended for agricultural purposes and can be used for the incubation of eggs from any poultry bird at a homestead or a private household as well as in small business or for breeding poultry in small quantities. The small-sized incubator comprises a housing, preferably having the form of a parallelepiped, configured to have a frame structure (1); a heat-insulating cover (4), a heating element (11), a humidifier (13), a fan (14), at least one egg tray configured to rotate eggs, a temperature sensor and a humidity sensor, a control unit configured to be connected to a backup power unit, according to the invention, the said frame housing is configured to be assembled and disassembled with connectors (3); the said heating element is located on or directly above the inner surface of the heat-insulating cover; the incubator is equipped with an emergency fan (15) located on the top of the housing. Further, for another embodiment of the small-sized incubator which differs from the first one in that the humidifier is configured to be a high frequency membrane equipped with a reflector, which, according to yet another feature of the invention claimed, is located above the membrane at an angle from 30 to 60 to the membrane. The application of the present invention allows us to create an energy-efficient small-sized incubator with highly-reliable operation in a given range of air temperature and humidity by positioning heating, ventilation and humidification elements in the design of the incubator and, at the same time, by improving the ease of its operation and providing an opportunity for thorough cleaning by configuring the housing and the heat-insulating cover of the incubator so that the said elements are made assemblable and disassemblable.

The invention relates to household appliances intended for agricultural purposes and can be used for the incubation of eggs from any poultry bird at a homestead or a private household as well as in small business or for breeding poultry in small quantities. The small-sized incubator comprises a housing, preferably having the form of a parallelepiped, configured to have a frame structure (1); a heat-insulating cover (4), a heating element (11), a humidifier (13), a fan (14), at least one egg tray configured to rotate eggs, a temperature sensor and a humidity sensor, a control unit configured to be connected to a backup power unit, according to the invention, the said frame housing is configured to be assembled and disassembled with connectors (3); the said heating element is located on or directly above the inner surface of the heat-insulating cover; the incubator is equipped with an emergency fan (15) located on the top of the housing. Further, for another embodiment of the small-sized incubator which differs from the first one in that the humidifier is configured to be a high frequency membrane equipped with a reflector, which, according to yet another feature of the invention claimed, is located above the membrane at an angle from 30 to 60 to the membrane. The application of the present invention allows us to create an energy-efficient small-sized incubator with highly-reliable operation in a given range of air temperature and humidity by positioning heating, ventilation and humidification elements in the design of the incubator and, at the same time, by improving the ease of its operation and providing an opportunity for thorough cleaning by configuring the housing and the heat-insulating cover of the incubator so that the said elements are made assemblable and disassemblable.

Embodiments are generally directed apparatuses, methods, techniques and so forth to receive a sled manifest comprising identifiers for physical resources of a sled, receive results of an authentication and validation operations performed to authenticate and validate the physical resources of the sled, determine whether the results of the authentication and validation operations indicate the physical resources are authenticate or not authenticate. Further and in response to the determination that the results indicate the physical resources are authenticated, permit the physical resources to process a workload, and in response to the determination that the results indicate the physical resources are not authenticated, prevent the physical resources from processing the workload.

Technologies for optical communication in a rack cluster in a data center are disclosed. In the illustrative embodiment, a network switch is connected to each of 1,024 sleds by an optical cable that enables communication at a rate of 200 gigabits per second. The optical cable has low loss, allowing for long cable lengths, which in turn allows for connecting to a large number of sleds. The optical cable also has a very high intrinsic bandwidth limit, allowing for the bandwidth to be upgraded without upgrading the optical infrastructure.

A nitrogen-oxide (NOx) sensor control system includes a NOx sensor analog front-end, a temperature sensor analog front-end, and a processing system. The NOx sensor analog front-end is adapted to receive analog NOx sensor signals from a NOx sensor and is configured to convert the analog NOx sensor signals to digital NOx sensor signals. The temperature sensor analog front-end is adapted to receive analog temperature sensor signals from a temperature sensor and is configured to convert the analog temperature sensor signals to digital temperature sensor signals. The processing system is coupled to receive the digital NOx sensor signals and the digital temperature sensor signals and is configured, in response thereto, to: supply the digital NOx sensor signals to an external system, and control a flow of current to a heater element in the NOx sensor.

A method of forming structure includes providing a substrate in a reaction chamber, forming a first layer overlaying the substrate, and forming a second layer onto the first layer. Temperature of the first layer is controlled during the forming of the first layer using infrared electromagnetic radiation emitted by the first layer. Temperature of the second layer is controlled during the forming of the second layer using infrared electromagnetic radiation emitted by the second layer. Semiconductor device structures and semiconductor processing systems are also described.

A system and method of operating a water supply system with one or more water consuming appliances includes a water heater fluidly coupled to a water consuming appliance through a supply conduit. The water consuming appliance includes an appliance communication module for communicating a target temperature. A mixing valve is positioned on the supply conduit, is in operative communication with the appliance communication module, and heats water from the water heater and cold water from the water supply to provide a flow of supply water to the water consuming appliance at the target temperature.