Abstract: The INTERIOR USER-COMFORT ENERGY EFFICIENCY MODELING AND CONTROL SYSTEMS AND APPARATUSES (“IUCEEMC”) transforms comfort maps and occupant comfort inputs via a profile library manager component, exploration manager component, comfort map manager component, regulation monitor component, control temperature sequence generator component, and comfort map modification component, into comfort map and control temperature sequence outputs. In some implementations, the IUCEEMC can divide a timespace of a temperature model into a plurality of sections, select a section from the plurality of sections, perform a first persistent change of the section from the plurality of sections, and, via a control temperature sequence generator, calculate a control temperature sequence using the temperature model. The IUCEEMC can develop and execute a temperature trajectory on an HVAC system, such as a home or industrial HVAC system.

Abstract: A sub-printing method for a 3D printer (1) includes following steps: obtaining slicing data (3) of a printing layer by the 3D printer (1) when performing printing; executing a logical segmentation action on the slicing data (3) according to a default segment-template (101) for generating multiple printing blocks (4); labelling each printing block (4) according to a default printing rule for deciding printing orders of the multiple printing blocks (4); controlling the 3D printer (1) to perform multiple sub-printing actions successively according to the printing blocks (4) based on the decided printing orders; and, re-executing above steps before all printing layers of a 3D model are completely printed.

Abstract: In an example, a method for forming a composite part includes, based on a part specification, cutting layers of material in a sequence and positioning the layers to form a stack. For each layer, after positioning the layer and before cutting a next layer in the sequence, the method includes (i) scanning along a length of the layer to determine an image, (ii) determining, based on the image, at least two edges of the layer, (iii) determining, based on the edges, a measured width at locations along the length of the layer, (iv) comparing the measured width at each location to a target width at the location, (v) deciding, based on the comparison, whether to adjust the production process, and (vi) if the decision is to adjust the production process, then adjusting the production process based on the comparison. The part specification specifies the target width at each location.

Abstract: A control system of a machine tool includes an analysis device, the analysis device includes acquisition portions which acquire chronological speed control data when a work is machined and which acquire spatial machined surface measurement data after the machining of the work, a data-associating processing portion which associates the speed control data and the machined surface measurement data with each other, a machined surface failure detection portion which detects a failure depth of a failure location on the machined surface of the work and an identification portion which identifies the control data of the failure location corresponding to the machined surface measurement data of the failure location so as to identify a failure depth corresponding to the control data of the failure location and the numerical control device corrects the control data based on the control data of the failure location and the corresponding failure depth.

Abstract: According to certain embodiments, a system comprises a primary unit and a plurality of secondary units each having a unique unit number. The primary unit is configured to communicate a command to each secondary unit with instructions to reply during a time window. The primary unit is also configured to receive a reply communication indicating the secondary unit's unique unit number from at least one of the secondary units, and determine an address to assign to the replying secondary unit based at least in part on the received unique unit number.

Abstract: In a method for setting a mounting position of a target substrate, the test substrate is transferred to a second position deviated from a first position. A mask has expected arrangement position where a non-film formation region has a preset width when the target substrate is mounted at the first position and subjected to a film formation. The film is formed on the test substrate at the second position by using the mask. Width of the non-film formation region formed on the test substrate after the film formation is measured. Actual arrangement position of the mask is specified based on a direction and a distance of the deviation of the second position from the first position and the measured width of the non-film formation region. The first position is corrected such that the non-film formation region has the preset width based on the actual arrangement position of the mask.

Abstract: A control system comprising a feedback controller 1 for determining an operation amount u in a control-implemented system based on a command value r*, a detection value y of the control-implemented system and phase information ? for the control-implemented system, wherein the feedback controller 1 has a periodic disturbance suppression controller 4 for outputting a periodic disturbance compensation signal rpd* based on the detection value y and the phase information ?; and a resonance/disturbance suppression controller 3 for calculating the operation amount u based on the detection value y and a corrected command value r obtained by adding the periodic disturbance compensation signal rpd* to the command value r*. The periodic disturbance suppression controller 4 uses a generalized periodic disturbance observer. In the control system, resonance, non-periodic disturbances and periodic disturbances are all suppressed in order to raise the system control performance.

Abstract: A robot transferring system of a component and a transferring method thereof are provided. The robot transferring system of a component includes a hanger in which components including at least one of a cowl plate, a roof rail, and a package tray are disposed. A first sensor detects a reference position of the components disposed in the hanger to detect a shape of the component and a first loading robot capture each component based on a predetermined position determined by the sensor. A first loading jig is disposed at a location in which one of the components captured by the loading robot is disposed and a setting robot transfers the components disposed in the loading jig to a vehicle body to dispose the component to a predetermined position of the vehicle body.

Abstract: An engine control system includes an electronic hardware engine controller and an actuator that operates at different positions to control operation of an engine. An actuator sensor measures an actuator position, and the engine controller generates a synthesized actuator position. In response to detecting a faulty actuator, a faulty actuator sensor, or both, the engine controller adjusts the position of the actuator based on the synthesized actuator position.

Abstract: A refinery or petrochemical plant may include a fractionation column and related equipment, such as one or more condensers, receivers, reboilers, feed exchangers, and pumps. The equipment may have boundaries or thresholds of operating parameters based on existing limits and/or operating conditions. Illustrative existing limits may include mechanical pressures, temperature limits, hydraulic pressure limits, and operating lives of various components. There may also be relationships between operational parameters related to particular processes. For example, the boundaries on a naphtha reforming reactor inlet temperature may be dependent on a regenerator capacity and hydrogen-to-hydrocarbon ratio, which in turn may be dependent on a recycle compressor capacity. Operational parameters of a final product may be determined based on actual current or historical operation, and implemented in one or more models to determine adjustments for enhanced operational efficiency.

Abstract: A controller assembly controls water flow through individual emitters of a heating/cooling system based on a temperature setpoint and room temperature indicator obtained from an associated thermostat. The controller assembly provides delta temperature room control using a high precision movement actuator fitted with two pipe temperature sensors to power modulate individual radiators, underfloor heating circuits or fan-coils to provide energy efficiency for individual room heating/cooling control. Based on the temperature difference between the room temperature and the setpoint the controller assembly controls water flow through the emitter by adjusting a valve to attain a target temperature delta between the inlet and outlet of the emitter. As the room temperature approaches the setpoint so that the temperature difference decreases, the power output of the emitter is modulated to achieve desirable performance characteristics.

Abstract: A system, method and apparatus providing fully automatic control of energy consuming or producing devices within a building or group of buildings, the system automatically reprogramming a power consumption controller (PCC) responsive to a failure to achieve a performance goal for a respective controlled device and automatically replacing the PCC responsive to a continued failure to achieve the performance goal.

Abstract: A method and a computer system for reducing noise are provided. The method includes: setting the computer system's operating mode to normal mode or low-noise mode by a processing unit according to a selection signal; measuring an operating temperature of the processing unit; controlling a rotational speed of a fan unit conducive to dissipation of heat from the processing unit according to the operating temperature by a fan-control unit in normal mode; detecting the operating temperature according to a first threshold and starting an overheat-protection mechanism by the processing unit in normal mode when the operating temperature reaches the first threshold; shutting down the fan unit by the fan-control unit in low-noise mode; and detecting the operating temperature according to a second threshold lower than the first threshold and starting the overheat-protection mechanism by the processing unit in low-noise mode when the operating temperature reaches the second threshold.

Abstract: Apparatus and associated methods relate to a distance-learning safety retraction device (DLSRD) mechanically coupled to a fixed anchor point on a boundary-mapped surface, the DLSRD including two receivers in operable communication with a transmitter borne on a user. In an illustrative example, the DLSRD may determine an angle between a lanyard coupled to the user and a vertical plane between the two receivers. The DLSRD may include, for example, an extraction detector detecting an extracted length of the lanyard. The DLSRD may determine user proximity to a safe operating area boundary based upon a difference of a current extracted length of the lanyard to a learned extracted length associated with a current angle of the lanyard, for example. Various DLSRDs may be configured in a run-mode to apply a braking effect to the lanyard and/or to activate a warning device based upon the user's proximity to the boundary.

Abstract: An intelligent vehicle charging system for charging a fleet of autonomous vehicles throughout a network of charging stations dispersed throughout a geographic area. The intelligent vehicle charging system includes a remote control system that is in operative communication with each of the autonomous vehicles in the fleet and each of the charging stations in the network. When an autonomous vehicle is in need of a power charge, or as directed by the remote control system, the remote control system will identify an available charging station, guide the autonomous vehicle to the charging station, verify that the autonomous vehicle has arrived at the charging station, initiate the power charging process, account and bill appropriate fees for the charging process, and log all associated activity. The remote control system is also capable of remotely and instantaneously terminating the power charging process to dynamically return a vehicle back to service.

Abstract: Methods and systems for predicting deformation error and compensating for shape deviation in Additive Manufacturing (AM) techniques include, in one aspect, a method including: obtaining a deformation model for an AM machine; predicting deformation for the object using the deformation model applied to the 3D model; selecting an amount of deformation compensation to effect by minimizing deviation for the predicted deformation; and providing the selected amount of deformation compensation to modify the 3D model to compensate for deformation during creation by the AM machine.

Abstract: A method for replacing a controller on a process device that avoids downtime on a process line. The method may include retrieving data from a first controller on a valve assembly, the data comprising information that defines values for operating parameters on the first controller, removing the first controller from the valve assembly, coupling a second controller to the valve assembly, and storing data on the second controller, the data comprising information that defines the values for operating parameters corresponding with the first controller.

Abstract: A digitally controlled power supply apparatus includes: a switching device converting an input voltage to output a converted voltage based on gate signals that it has received; a smoothing circuit smoothing the converted voltage to output a power supply voltage; an AD converter AD converting the power supply voltage from the smoothing circuit to output a power supply voltage digital data; a PID controller performing PID control operation to an error between a setpoint and the power supply voltage digital data; a switching drive circuit generating gate signals, based on an operation outcome of the PID controller; a control parameter adjuster dynamically performing automatic adjustment of control parameters of the PID controller, based on a history of fluctuations indicated in samplings of the power supply voltage digital data; and a control parameter output unit outputting the control parameters of the PID controller.

Abstract: A control system includes a control device that repeatedly performs a series of pieces of processing including I/O refresh processing and program execution processing. The control system includes: a first obtainment unit that obtains a first sample value group collected by repeatedly performing the I/O refresh processing in a first control period; a second obtainment unit that obtains a second sample value group collected by repeatedly performing the I/O refresh processing in a second control period longer than the first control period; a determination unit that determines whether a first frequency component in the first sample value group and a second frequency component in the second sample value group are substantially identical to each other; and a change unit that changes the first control period to the second control period under a condition that the first frequency component and the second frequency component are substantially identical to each other.

Abstract: Apparatuses, methods, and program products are disclosed for controlling appliances. One apparatus includes a processor, and a memory that stores code executable by the processor. The code is executable by the processor to detect a usage history of multiple types of appliances in a building. The code is executable by the processor to determine changes to operation of the multiple types of appliances based on the usage history. The code is executable by the processor to control the multiple types of appliances based on the determined changes to the operation of the multiple types of appliances.