A failure detection device includes a formaldehyde sensor that detects the generation of formaldehyde, a vibration sensor that detects vibration of a spindle head, and a machine controller that detects the occurrence of an abnormality of a spindle bearing. The machine controller determines the occurrence of the abnormality of the spindle bearing and a cause of the abnormality based on a change in the output value of the formaldehyde sensor over time and a change in the output value of the vibration sensor over time.

A motor control system includes a motor control apparatus, a motor, an environment state detector, and an operation state monitor. The motor control apparatus is configured to control feeding of driving power based on a control command. The motor is drivable by the driving power. The environment state detector is configured to detect environment state data of at least one of the motor control apparatus and the motor. The operation state monitor is configured to output, based on the environment state data, an operation margin of an operation state value of the at least one of the motor control apparatus and the motor relative to an operation rated value of the at least one of the motor control apparatus and the motor.

A thermostat includes a memory configured to store operating conditions for previously run conditioning events. The thermostat further includes a controller configured to receive first temperature data from a first temperature sensor indicative of a current indoor ambient temperature inside; receive second temperature data from a second temperature sensor indicative of a current outdoor ambient temperature outside; receive a temperature setpoint for a desired indoor ambient temperature of the building; determine a severity of a call for conditioning based on at least one of the current indoor ambient temperature, the current outdoor ambient temperature, and the temperature setpoint; and operate the multi-stage HVAC system in one of the plurality of stages for a current conditioning event based on the severity of the call for conditioning and the operating conditions for a similar previously run conditioning event to drive the current indoor ambient temperature towards the temperature setpoint.

An analysis and/or treatment device (100) for at least one smoking article (60). comprising a closable receptacle (4) for receiving the at least one smoking article (60) therein; a reservoir (62) for a fluid treatment material (8, 9); a hollow injection needle. (2) interiorly insertable into the smoking article (60) received in the receptacle (4) and operably connected to the reservoir (62); means (3) for moving the treatment material (9) from the reservoir (62) through the needle (2) into the interior of the smoking article (60); and at least one sensor means (15) provided in the receptacle (4) for detecting at least one parameter characterizing a property of the smoking article (60) and/or characterizing the treatment conditions in the receptacle (4). A method for applying a treatment to a smoking article (60), wherein the smoking article (60) is enclosed by a receptacle (4), and a treatment material (8,9) is inserted into the receptacle (4) and directly into the interior of the smoking article (60) as a function of parameters measured by sensor means (1), said parameters being indicative of at least one of the temperature and the humidity in the receptacle (4) and the smoking article (60).

An apparatus to assist a machinist in the setup of a remote computer controlled machine tool table has an X-axis electronic gauge block assembly, a Y-axis electronic gauge block assembly, and a Z-axis electronic gauge block assembly each positioned on the machine tool table, to respectively collect X-axis probe position values, Y-axis probe position values, and Z-axis probe position values. Environmental sensors collect environmental values. An electronics processing system establishes a raw X-axis probe position, a raw Y-axis probe position, and a raw Z-axis probe position. A wireless interface transmits the environmental values, the raw X-axis probe position value, the raw Y-axis probe position value, and the raw Z-axis probe position value to the remote computer and receives from the remote computer refined probe position values to assist the machinist in the setup of the machine tool table.

A building HVAC system includes an airside system having a plurality of airside subsystems, a high-level model predictive controller (MPC), and a plurality of low-level airside MPCs. Each airside subsystem includes airside HVAC equipment configured to provide heating or cooling to the airside subsystem. The high-level MPC is configured to perform a high-level optimization to generate an optimal airside subsystem load profile for each airside subsystem. The optimal airside subsystem load profiles optimize energy cost. Each of the low-level airside MPCs corresponds to one of the airside subsystems and is configured to perform a low-level optimization to generate optimal airside temperature setpoints for the corresponding airside subsystem using the optimal airside subsystem load profile for the corresponding airside subsystem. Each of the low-level airside MPCs is configured to use the optimal airside temperature setpoints for the corresponding airside subsystem to operate the airside HVAC equipment of the corresponding airside subsystem.

A building HVAC system includes an airside system having a plurality of airside subsystems, a waterside system, a high-level model predictive controller (MPC), and a plurality of low-level airside MPCs. Each airside subsystem includes airside HVAC equipment configured to provide heating or cooling to the airside subsystem. The waterside system includes waterside HVAC equipment configured to produce thermal energy used by the airside system to provide the heating or cooling. The high-level MPC is configured to perform a high-level optimization to generate an optimal airside subsystem load profile for each of the plurality of airside subsystems. The optimal airside subsystem load profiles optimize a total cost of energy consumed by the airside system and the waterside system Each of the low-level airside MPCs is configured to operate the airside HVAC equipment of an airside subsystem according to the load profile for the airside subsystem.

A method of remotely managing a transport climate control system (TCCS) includes a remote management device receiving performance data from the TCCS. The performance data based on one or more detected operating parameters of the climate control circuit. The method also including the remote management device providing the performance data to one or more user devices. A remote management system includes a remote management device configured to receive performance data for a climate control circuit from a climate controller of a TCCS and to provide the performance data to one or more user devices. A TCCS includes a controller configured to: generate performance data based on the one or more detected operating parameters of a climate control circuit, and transmit the performance data to a remote monitoring device. The climate controller also configured to receive an operating instruction from the remote monitoring device.

A thermostat includes a memory configured to store operating conditions for previously run conditioning events. The thermostat further includes a controller configured to receive first temperature data from a first temperature sensor indicative of a current indoor ambient temperature inside; receive second temperature data from a second temperature sensor indicative of a current outdoor ambient temperature outside; receive a temperature setpoint for a desired indoor ambient temperature of the building; determine a severity of a call for conditioning based on at least one of the current indoor ambient temperature, the current outdoor ambient temperature, and the temperature setpoint; and operate the multi-stage HVAC system in one of the plurality of stages for a current conditioning event based on the severity of the call for conditioning and the operating conditions for a similar previously run conditioning event to drive the current indoor ambient temperature towards the temperature setpoint.

State of the art systems used for monitoring of land (for example, agricultural land), fail to accurately assess various conditions in the land area and make predictions. The disclosure herein generally relates to agricultural systems, and, more particularly, to a method and system for micro-climate management in a land area being monitored. The system groups the different plots based on sensor trend information and based on a determined homogeneity information. A micro-climate view of the land area is accordingly generated, which in turn is used to generate micro-climate predictions.