Apparatuses, methods, systems, and program products are disclosed for an automated container kiosk. An apparatus includes a request module configured to receive a request over a data network to unlock a door of a container. An apparatus includes a payment module configured to determine whether one or more payment conditions is satisfied for one or more items within a container. An apparatus includes a security module configured to, in response to determining that one or more payment conditions is satisfied, receive unlock information for unlocking a door of a container and enable one or more security measures for monitoring activity within the container.

Controller technology, in which data specifying a user preference relating to an environmental parameter for a property is received. Based on data collected by a monitoring system, a location of one or more users within the property is identified. Environmental condition data for the property is accessed, the environmental condition data including environmental condition data for the location of the users within the property and other unoccupied locations within the property. The environmental condition data for the property is analyzed with respect to the preference relating to the environmental parameter for the property. Based on the analysis of the environmental condition data for the property with respect to the preference relating to the environmental parameter for the property, a setting for at least one component of an HVAC system is determined. The at least one component of the HVAC system is controlled according to the determined setting.

A controller for a plurality of devices of a building control system that operate in parallel to provide a desired capacity of heating or cooling for a building space includes a capacity identifier configured to identify the desired capacity of heating or cooling for the building space. The controller further includes a combination finder configured to generate a list of combinations of devices that can be energized to provide the desired capacity. The controller further includes a combination filter configured to remove any combinations from the list that do not meet one or more requirements. The controller further includes a combination selector configured to select one of the combinations based on at least one of a runtime and a transition count. The controller further includes a signal generator configured to generate control signals in accordance with the selected combination and operate the plurality of devices using the control signals.

Provided are a method and an arrangement for operating a metallurgical furnace. The method comprises a feeding step, and a temperature controlling step for controlling the temperature of a molten metal layer and a slag layer in a furnace space of the metallurgical furnace. The temperature controlling step comprises a first measuring step for measuring the slag temperature (T.sub.slag), a second measuring step for measuring the slag liquidus temperature (T.sub.slag, liquidus), and a calculating step for calculating a superheat temperature (T.sub.superheat) by calculating the temperature difference between the slag temperature (T.sub.slag) and the slag liquidus temperature (T.sub.slag, liquidus). In case the calculated superheat temperature (T.sub.superheat) is outside a predefined superheat temperature range (T.sub.superheat set), the method comprises an adjusting step for adjusting to adjust the actual superheat temperature. Also provided are computer program products.

A building HVAC system includes an airside system having a plurality of airside subsystems, a high-level controller, and a plurality of low-level airside controllers. Each airside subsystem includes airside HVAC equipment configured to provide heating or cooling to one or more building spaces. The high-level controller is configured to generate a plurality of airside subsystem energy targets, each airside subsystem energy target corresponding to one of the plurality of airside subsystems and generated based on a thermal capacitance of the one or more building spaces to which heating or cooling is provided by the corresponding airside subsystem. Each low-level airside controller corresponds to one of the airside subsystems and is configured to control the airside HVAC equipment of the corresponding airside subsystem in accordance with the airside subsystem energy target for the corresponding airside subsystem.

Various examples of the present disclosure provide a multi-node fan control switch and systems and methods for controlling one or more cooling fans of a node using a fan control switch and a specific controller (e.g., BMC or a specific processor) of the node. The node also includes a watch dog circuit. The watch dog circuit can monitor health of the specific controller and, in response to determining that the specific controller has failed, enable the fan control switch to an external mode to allow a controller of a neighboring node in the rack system to control the one or more cooling fans of the node.

A nuclear medicine tomography system including: a detector carrier; a detector carrier housing including an inner space; a plurality of detector units, coupled to the detector carrier, each detector unit comprising: a detector camera; a cooling channel which guides air to the detector camera from the inner space; an exhaust channel which guides air from the detector camera to the inner space; a heat pump configured to cool air within the inner space.

A monitoring system is disclosed for a heating, ventilation, or air conditioning (HVAC) system of a residential or commercial building. The monitoring system includes an evaporator unit device including a first current sensor that measures current supplied to a circulator blower. The measured current from the first current sensor is used to diagnose a problem with the circulator blower. The monitoring system includes a first temperature sensor that measures refrigerant temperature between a condenser and an expansion valve. The monitoring system includes a second temperature sensor that measures refrigerant temperature between an evaporator and a compressor. The monitoring system includes a condenser unit device that communicates with the evaporator unit device. The condenser unit device includes a second current sensor that measures current supplied to the compressor. The evaporator unit device transmits sensor data to a remote monitoring service over a data network.

According to certain embodiments, a device is configured for use in a climate control system. The device is operable to determine, based on configuration information, whether thermostat functionality of the device is enabled or disabled and whether sensor functionality of the device is enabled or disabled. The device is further operable to operate according to the configuration information. Thus, according to certain embodiments, the device can be configured as a thermostat, a sensor, or both.

Various arrangements for monitoring and controlling operation of a HVAC system are provided. Battery-operated temperature monitoring devices may be situated within the structure and connected with a network. A user command may be received that includes a selection of at least one of the battery-operated temperature monitoring devices. An offset may be calculated based on an evaluation of a first temperature reading of the selected battery-operated temperature monitoring device relative to a second temperature reading of the thermostat. The offset may be overridden when an override condition is present.