Abstract: An example sinter system includes a sinter gas inlet at a sinter furnace for a sinter gas, a tracer gas inlet at the sinter furnace for a tracer gas different from the sinter gas, and an outlet at the sinter furnace to output the sinter gas and the tracer gas. The example sinter system further includes: a support structure to support a sample green object in the sinter furnace, an opening at the support structure connected to the tracer gas inlet, the opening to output the tracer gas into the sinter furnace, and a detector to: determine an amount of the tracer gas flowing through the outlet during a sinter process as a sample green object positioned on the support structure changes shape during the sinter process with respect to the opening and modifies a flow rate of the tracer gas to the outlet; and determine when to stop the sinter process based on a determined amount of the tracer gas.

Abstract: An oven can include an oven body including a set of interior panels. A set of exterior panels are spaced from the set of interior panels such that a channel is defined between the set of interior panels and the set of exterior panels. The set of interior panels includes an interior panel peripheral wall and an interior panel top wall that at least partially define a cooking cavity. Each interior panel of the set of interior panels has an inner surface and an outer surface. The oven further includes an imaging device with a field of view including at least a portion of the cooking cavity. The oven also comprises a damper coupled to the oven body and to the imaging device for absorbing mechanical vibrations associated with airflow generated by the fan.

Abstract: Provided herein is a method of neutralizing cotton seeds, including the steps of providing delinted cotton seeds having a pH of less than about 3.3, and applying an alkyl amine to the delinted cotton seeds to produce neutralized delinted cotton seeds having a pH of greater than about 3.5.

Abstract: An oven can include an oven body including a set of interior panels. A set of exterior panels are spaced from the set of interior panels such that a channel is defined between the set of interior panels and the set of exterior panels. The set of interior panels includes an interior panel peripheral wall and an interior panel top wall that at least partially define a cooking cavity. Each interior panel of the set of interior panels has an inner surface and an outer surface. Insulation is located in at least a portion of the channel. The oven further includes an imaging device with a field of view including at least a portion of the cooking cavity.

Abstract: An oxidation furnace for the oxidative treatment of fibers having a housing which is gas-tight, apart from passage areas for the fibers, and a process chamber located in the interior of the housing. A hot working atmosphere can be generated by an atmosphere-generating device, can be blown into the process chamber and flows through the process chamber in processing conditions in a main direction of flow. Deflecting rollers guide the fibers through the process chamber in a serpentine manner in such a way that the fibers lie next to one another as a fiber carpet (22a), wherein the fiber carpet spans a plane between opposite deflecting rollers. A flow measuring system is provided, by means of which a flow profile of the working atmosphere in processing conditions can be generated, and which comprises at least one sensor system for determining the speed of flow, the sensor system being arranged in a sensor region between two adjacent fiber carpets.

Abstract: A furnace for a dental prosthesis or a partial dental prosthesis, in particular for dental ceramic, comprising a firing chamber which can be heated and in particular can also be evacuated, a control device for controlling the operation of the furnace on the basis of a firing program, which is based on a set of parameter values, and an operator control unit, which is assigned to the control device and is designed to display a representation of the firing program in the form of a firing process curve, wherein the operator control unit can be used in a simplified operating mode in which it displays together with the firing process curve at least one operator control area for adjusting a selected parameter value of the set of parameter values that relates to a prescribed program phase of the firing program, wherein the at least one operator control area is permanently arranged in the area of the displayed firing process curve that corresponds to the prescribed program phase.

Abstract: A heat controlled oven system includes a plurality of oven levels, including an oven belt and gas burners; a gas flow network, including a gas supply line, a variable flow control valve, and on/off flow control valves; and a heat control unit, including a processor, a non-transitory memory, and input/output component, a heat modeler, a heat manager, a feedback controller, and a valve controller, such that the heat control unit is configured to calculate an estimated heat demand to adjust to a temperature set point, based on a heat model of the at least one oven level, and further calculates an optimized heat demand using a control loop feedback algorithm. Also disclosed is a method of heat calculation for an oven, including defining a heat model, calculating and optimizing the estimated heat demand, calculating and setting a variable valve position for the gas burners.

Abstract: A work is subjected to a heat treatment in a heat-treating furnace. First, the work is carried into the heat-treating furnace. The work in the heat-treating furnace is immersed in a heat source solvent. In the heat-treating furnace, a superheated steam atmosphere is formed. The work is exposed in the heat-treating furnace under the superheated steam atmosphere. Then, the work is carried out of the heat-treating furnace.

Abstract: Disclosed herein is a system for monitoring a heating apparatus that includes a motion detector configured to determine whether a person is proximate the heating apparatus. The motion detector is default deactivated. Further disclosed is a heat sensor configured to determine whether the heating apparatus has a temperature that is above a threshold. The heat sensor is default deactivated. A processor is in operable communication with each of the motion detector and the heat sensor configured to cyclically repeat a first countdown. The heat sensor is temporarily activated once during each of the repeated first countdowns. The processor is configured to perform a second countdown when the activated heat sensor determines that the heating apparatus has the temperature that is above the threshold. The second countdown is reset each time the motion detector determines that a person is proximate the heating apparatus.

Abstract: A control device for gas appliances (1) comprises: a manual-control element (12, 22); a circuit arrangement (25a) that includes control elements, electrical-interconnection elements, detection elements for detecting actuation of the manual-control element (12, 22) and supplying corresponding signals to the control elements; and a supporting structure (21), which can be associated in a stationary way with respect to a gas tap, wherein the supporting structure (21) includes at least one first part of stationary structure (40, 41) that defines a housing for at least part of the circuit arrangement (25a), the first part of structure (40, 41) being in particular designed for being housed within a body of a gas appliance. The control elements are designed for counting the time, and the device includes optical warning elements (43?, LG).

Abstract: In the specification and drawings, an apparatus for conducting hot work is described and shown with an enclosure; a hot work apparatus operable within the enclosure; and a detector located exterior of the enclosure, the detector being in detecting communication with the interior of the enclosure, such that the detector detects the presence of a condition within the enclosure. A method of conducting hot work is also described and shown.

Abstract: Provided is a substrate processing apparatus capable of improving the workability of measuring a temperature-flat zone in a process furnace and the reliability of a temperature-flat length of a heater. The substrate processing apparatus includes a process chamber configured to process a substrate retained in a retainer loaded therein; a temperature measuring device configured to measure an inside temperature of the process chamber; a transfer device configured to transfer the substrate at least to the retainer; and a controller configured to control the transfer device and the temperature measuring device to move the transfer device to a predetermined position before the inside temperature of the process chamber is measured and to obtain the inside temperature by the temperature measuring device while vertically moving the transfer device with the temperature measuring device attached to the transfer device when the inside temperature of the process chamber is measured.

Abstract: A temperature measurement apparatus for estimating a temperature profile in a process container, includes a radiation temperature measurement unit configured to measure the temperature of plural temperature measurement areas at a surface of the rotating table in a radius direction of the rotating table by scanning the surface of the rotating table in the radius direction; an operation control unit that controls to start heating of the process container by a heater while keeping the rotating table immobilized, and controls to repeat a scanning operation, in which the radiation temperature measurement unit scans the surface of the rotating table in the radius direction to obtain the temperature of the plural temperature measurement areas while the rotating table is rotated in a circumferential direction of the rotating table, after a predetermined period has passed from starting the heating of the process container.

Abstract: There are provided a method for heat treatment, a heat treatment apparatus, and a heat treatment system capable of efficiently controlling heat treatment such as a bright treatment with high precision and without causing oxidation and decarbonization. Computation of ?G0 (standard formation Gibbs energy) is performed by referring to sensor information from respective sensors, and an Ellingham diagram, a control range, and a status of the heat treatment furnace in operation expressed with ?G0 are displayed on a display device 531, while a flow rate of hydrocarbon gas is controlled by a control unit 534 so that ?G0 is within the control range.

Abstract: According to one embodiment, a system for a decoloring information management of a decoloring apparatus includes an decoloring processing unit, a sheet conveying unit, a sheet reading unit, a user ID reading unit, a storing unit configured to store a predetermined information, and a control unit. A sheet on which an image is formed with an decolorable colorant is subject to decoloring processing. The sheet conveying unit conveys the sheet and causes the sheet to pass through the decoloring processing unit. The sheet reading unit is arranged further on an upstream side than the decoloring processing unit. The user ID reading unit reads ID information of a user. The storing unit stores predetermined information. The control unit controls the storage unit to correlate the user ID and the read information by the sheet reading unit.

Abstract: A heating apparatus including: a heating part which heats a substrate having coated thereon a liquid material containing a metal and a solvent, and a thermocouple which is disposed to contact a portion of the heating part and has at least a surface of a contact portion contacting the heating part covered with a protection film.

Abstract: A high temperature furnace comprising hot zone insulation having at least one shaped thermocouple assembly port to reduce temperature measurement variability is disclosed. The shaped thermocouple assembly port has an opening in the insulation facing the hot zone that is larger than the opening on the furnace shell side of the insulation. A method for producing a crystalline ingot in a high temperature furnace utilizing insulation having a shaped thermocouple assembly port is also disclosed.

Abstract: A domestic appliance includes a first display area for displaying first operation settings of the domestic appliance, a first control element for selecting one of the first operation settings, a second display area for displaying second operation settings of the domestic appliance, a second control element for selecting one of the second operation settings. A control facility is provided to allocate a first two-dimensional extent to the first display region and a second two-dimensional extent to the second display region when a user actuates the first operating element and to allocate a third two-dimensional extent to the first display region and a fourth two-dimensional extent to the second display region when the user actuates the second operating element. The third two-dimensional extent is smaller than the first two-dimensional extent and the fourth two-dimensional extent is larger than the second two-dimensional extent.

Abstract: An apparatus for the application of hotmelt onto labels, includes a vacuum cylinder, a gluing unit with a glue roller unit, and a glue reservoir. The gluing unit is pivotally mounted such that it can be slewed away from the vacuum cylinder and the glue reservoir is designed as a self-contained unit that is structurally separate from the pivotable gluing unit. A glue reservoir for hotmelt includes an inner body with heating fins, a thermally insulating jacket enclosing the inner body, and an outer casing made of plastic.

Abstract: Embodiments of the invention generally relate to pyrometry during thermal processing of semiconductor substrates. More specifically, embodiments of the invention relate to a pyrometry filter for a thermal process chamber. In certain embodiments, the pyrometry filter selectively filters selected wavelengths of energy to improve a pyrometer measurement. The pyrometry filter may have various geometries which may affect the functionality of the pyrometry filter.

Abstract: The invention relates to a measuring apparatus comprising a coating probe and a probe holder which is disposed on a wall of a sample chamber. The coating probe is displaceable into the sample chamber on one side and is displaceable out from the sample chamber on the opposite side. As a result, practical investigations of boiler coatings are made possible.

Abstract: The present invention relates to a device (100) for the heat treatment of substrates and to a method for recording measurement data in said device, where said device (100) comprises at least one heatable chamber (102), a carrier system (108), a sensor assembly (112), and an actuator (111) that is independent of the carrier system (108). The carrier system (108) is designed to carry substrates, whereas the sensor assembly (112) is further configured for coupling to a data recording and/or data storage device (130). The actuator (111) is coupled to the sensor assembly (112) and is configured to position the sensor assembly (112) within the heatable chamber (102).

Abstract: A method for detecting straightness deviations and/deformations in a rotary kiln (1), the rotary drum (4) of which includes bearing rings (6) spaced apart from one another in the axial direction and respectively supported on rollers (7), involves scanning the outer surface area (5) of the rotary drum (4), the bearing rings (6), the rollers (7) and/or the shafts (17) of the rollers (7) in a contactless fashion with the aid of at least one scanning device (12) such that three-dimensional position data regarding the scanned objects is obtained, and evaluating the three-dimensional position data with respect to the occurrence of a deviation of the rotary kiln axis (3) from a straight line, a deviation of the rotary drum (4) from a cylindrical shape and/or a deviation of the rotational axes (8) of the rollers from a line extending parallel to the rotary kiln axis (3). A device for detecting straightness deviations and/or deformations in a rotary kiln (1) is also provided.

Abstract: A vacuum heat treatment apparatus according to the embodiment comprises a chamber; a thermal insulator in the chamber; a reaction container in the thermal insulator; a heating member between the reaction container and the the thermal insulator for heating the reaction container; and a temperature measuring member in or on a surface of the reaction container, wherein the temperature measuring member comprises a thermocouple and a protective tube surrounding the thermocouple, and the protective tube comprises tungsten (W), tantalum (Ta), or silicon carbide (SiC).

Abstract: Provided are peptide analogues of PA-IL and compositions containing them. The PA-IL peptide analogues have altered carbohydrate binding specificity relative to a PA-IL of SEQ ID NO:1, and thus the analogues contain amino acid substitutions in SEQ ID NO:1. The substitutions can be at positions 50, 52 and 53 of SEQ ID NO:1 and can include combinations of amino acid substitutions at those positions. Also included are methods for detecting changes in the glycosylation of carbohydrates and for separating biomolecules which contain glycoproteins or glycoconjugates.

Abstract: The invention relates to a dental furnace comprising a firing hood equipped with a heating device that is movably supported for the opening and closing of the dental furnace relative to a base intended for receiving a dental restoration part, and further comprising a heat detection device that is directed towards an area above the base, in particular towards one or more dental restoration parts, and further comprising a control or regulating device for the dental furnace that is coupled to the heat detection device, wherein the heat detection device is configured as a thermal imaging camera (30) which is directed towards the area above the base while the firing hood (12) is partially or completely opened, and which feeds an at least two-dimensional image in the form of a matrix of the one or more inserted dental restoration parts (60) to the control or regulating device and/or to a muffle (26) that is intended for the generation of the dental restoration parts (60).

Abstract: An oven and an adjustable baking system are proposed. The oven includes a signal receiving module, a baking module, a detecting module, and a feedback module. The signal receiving module is used for receiving a ready-to-send signal sent by a developing apparatus in a previous process from the oven. The ready-to-send signal conveys information of preparing for transferring a glass substrate to the oven. The detecting module is used for detecting the robot to see if the robot takes the glass substrate out of the baking module. The feedback module is used for determining if a confirmation signal is sent back to the developing apparatus according to the detecting result from the detecting module. The confirmation signal conveys information that the developing apparatus should transfer the glass substrate to the feedback module.

Abstract: A heating assembly designed for reducing foodborne pathogens in bagged food products comprises a heat insulated treatment chamber, multiple high temperature natural gas fired furnaces, multiple insulated ductworks further comprising multiple sets of intake ducts and multiple sets of exhaust ducts, a cooling system that allows air to be controlled and supplied into the treatment chamber, multiple temperature sensor probes placed in the treatment chamber, the natural gas fired furnaces, and the bagged food products, a digital control system, and a computer program that monitors the temperature of each probe. A specially designed racking system with multiple levels allows multiple dry bags containing the food products to be stacked in a manner that rapidly and uniformly heat the food products.

Abstract: An energy-saving and heat preservation device is mainly a heat preservation device for heating device and receptacle. Upper and lower receiving slots opened to outside and opposite to upper and lower ends of a receptacle respectively are provided in the heating device, while a first and a second chambers opposite to each other are provided in the heat preservation device. Energy storage material, which is a reversible phase-change material, is received within the first chamber. A conduit is connected between the first and the second chambers to form an integral connection arrangement. Hence, waste heat generated in the heating process is collected and stored, and is used for heat preservation. Not only the exhausted waste heat, which later becomes heat load of air conditioning apparatus, can be reduced but also power consumption for heat preservation can be lowered.

Abstract: The present invention provides apparatus and methods to operate microreactor devices through the controlled delivery of pressurized fluids. A heated reservoir, a heated manifold, and a heater for the microreactor device provides for the delivery of a pressurized gas while minimizing evaporation and condensation; and a fluid interface and pressure interlock provides for the delivery of aseptic fluids while minimizing contamination and fluid loss.

Abstract: The present invention is directed to a flame detection device comprising a flame signal receiver (1), a flame signal passage (11) and a flame signal transmitting mechanism, characterized in that, the flame signal passage (11) passes through a furnace shell (12) into inner of the furnace and comprises an outside-furnace passage portion (11a) and an inside-furnace passage portion (11b); wherein a pressure-resistant optical mechanism (10) is arranged at the outermost end of the outside-furnace passage portion, said pressure-resistant optical mechanism hermetically and transparently separate the flame signal receiver from the flame signal passage; and wherein the inside-furnace passage portion (11b) is provided with a cooling mechanism (19).

Abstract: A heating control system comprises a vessel including a plurality of fluid ports including: a fluid inlet port arranged to connect to a heated fluid supply, a first controllable radiator circuit port, and a second controllable radiator circuit port. A controller is operatively connected to the controllable radiator circuit ports and to a temperature probe arranged to indicate, in use, a temperature of fluid circulating through the vessel. The controller is arranged to open a selected one of the radiator ports when the probe indicates the fluid is below a temperature T2 and to open the other of the radiator ports when the probe indicates the fluid is above the temperature T2.

Abstract: The invention relates to a method and equipment for starting up a strand sintering furnace (1). During start-up, the sintering furnace is heated in order to create suitable production temperatures in the different process zones (I-VII) having different temperatures, said zones including a drying zone (I), a heating zone (II), a sintering zone (III), an equalizing zone (IV), a first cooling zone (V), a second cooling zone (VI) and a third cooling zone (VII). During start-up, the cooling gas to be conducted to the second cooling zone (VI) is heated by means of a heating device (3) up to a temperature that is higher than the ambient temperature.

Abstract: A temperature measurement apparatus for estimating a temperature profile in a process container, includes a radiation temperature measurement unit configured to measure the temperature of plural temperature measurement areas at a surface of the rotating table in a radius direction of the rotating table by scanning the surface of the rotating table in the radius direction; an operation control unit that controls to start heating of the process container by a heater while keeping the rotating table immobilized, and controls to repeat a scanning operation, in which the radiation temperature measurement unit scans the surface of the rotating table in the radius direction to obtain the temperature of the plural temperature measurement areas while the rotating table is rotated in a circumferential direction of the rotating table, after a predetermined period has passed from starting the heating of the process container.

Abstract: A wafer temperature control apparatus comprises a first temperature sensor and a second temperature sensor. The first temperature sensor is configured to receive a first temperature signal from a center portion of a backside of a susceptor. The second temperature sensor is configured to receive a second temperature signal from an edge portion of the susceptor. A plurality of controllers are configured to adjust each heating source's output based upon the first temperature signal and the second temperature signal.

Abstract: A manufacturing method for a semiconductor device including: determining pattern dependency of a radiation factor of an element forming surface of one wafer having a predetermined pattern formed on the wafer; determining a heating surface of the wafer, based on the pattern dependency of the radiation factor; holding the one wafer having the determined heating surface and another wafer having a determined heating surface, spaced at a predetermined distance in such a manner that non-heating surfaces of the one wafer and the another wafer oppose to each other; and heating the each heating surface of the one wafer and the another wafer.

Abstract: The present disclosure describes, among other things, a method. The method may include determining, by a processor of a controller, a setting on a control, the setting corresponding to a type of connector. The method may include retrieving, by the processor, an algorithm for curing epoxy disposed within the type of connector. The method may include generating, by the processor, at least one control signal based at least in part on the algorithm. The method may include sending, by the controller, the at least one control signal to a heating dock.

Abstract: A thermal treatment apparatus includes a processing container, a substrate holding unit for holding a plurality of substrates at predetermined intervals in a direction inside the processing container, a heating unit for heating the processing container, a supply unit for supplying gas, a plurality of supply ports provided respectively at different locations in the direction, and a cooling unit for cooling the processing container by supplying the gas into the processing container by the supply unit via each of the supply ports, wherein the supply unit is provided in such a way that the supply unit independently controls flow rates of the gases supplied via each of the supply ports.

Abstract: A container for holding liquid is described. The container defines an inner region inside which liquid is adapted to be held and includes one or more walls for facilitating heating or cooling of the liquid therethrough, the one or more walls being adapted for invagination by a temperature control probe such that the temperature control probe extends into the container without directly contacting contents of the inner region of the container.

Abstract: A delayed coking heater for heating a feedstock to delayed coking temperature is disclosed. The delayed coking heater may include: a heater including a radiant heating zone comprising a lower portion including a hearth burner section and an upper portion including a wall burner section, the hearth burner section comprising a plurality of hearth burners located adjacent to the bottom hearth for firing in the radiant heating zone; and the wall burner section comprising a plurality of wall burners located adjacent to opposing walls; and a multiple parallel serpentine heating coil located in the radiant heating zone.

Abstract: A dental furnace (10), with a furnace head (including firing space 16) and a firing space bottom (12) is provided which is suited to accommodate a dental restoration part (40). At least one optical sensor (22) is positioned at the dental furnace (10) or in its vicinity, which sensor comprises an output port (26) which is connected to an evaluation device for evaluating the dental restoration part (40) and/or a muffle (14) and/or a press plunger (52) and/or a firing-charge carrier as far as its dimensions and/or its shape and/or its position are concerned.

Abstract: A dental furnace (10) for dental restorations comprising a firing chamber into which, in particular between a furnace bottom part (14) and a furnace upper part (12), the dental restoration, in particular within a muffle, can be introduced, and a sensor that is connected with a control device (52) for the dental furnace (10), wherein the sensor, in particular the temperature sensor (22), is arranged outside the firing chamber and comprises a detection range (40) that also extends outside the firing chamber.

Abstract: A batch of a substance, e.g., a biomass, is processed in a batch-wise operated retort under the application of heat. The substance releases a combustible process fluid during the processing. The process fluid is combusted for generating heat. The heat is supplied to the retort and/or stored in temporary heat storage in dependence on the progress of the processing for postponed heat supply to the retort.

Abstract: A heat treatment apparatus including: a processing container for processing wafers held in a boat; heaters for heating the processing container; and a control section for controlling the heaters. Heater temperature sensors are provided between the heaters and the processing container, in-container temperature sensors are provided in the processing container, and movable temperature sensors are provided in the boat. The temperature sensors are connected to a temperature estimation section. The temperature estimation section selects two of the three types of temperature sensors, e.g. the movable temperature sensors and the in-container temperature sensors, and determines the temperature of a wafer according to the following formula: T=T1×(1??)+T2×?, ?>1, where T1 and T2 represent detection temperatures of the selected temperature sensors, and ? represents a mixing ratio.

Abstract: A heat treatment apparatus includes: a furnace body including a heating part; a processing vessel wherein a space having a plurality of regions is formed between the furnace body and the processing vessel; an in-furnace temperature sensor disposed corresponding to each of the plurality of regions in the space; an in-furnace temperature calculating unit configured to calculate an in-furnace temperature based on signals from each of the in-furnace temperature sensors; and a control unit configured to control the heating part based on the in-furnace temperature calculated by the in-furnace temperature calculating unit. The in-furnace temperature sensor disposed in the reference region includes: a first thermocouple formed of an R thermocouple or an S thermocouple; and a second thermocouple formed of a thermocouple other than the R thermocouple or the S thermocouple. The in-furnace temperature sensor disposed in the other region includes the second thermocouple.

Abstract: A method and apparatus for heating and/or pressing sealant of an insulating glass unit. The apparatus may include an oven and a press. The oven includes a detector that detects an optical property of the insulating glass unit. The detected optical property is used to regulate the amount of energy applied to the insulating glass unit to adjust the amount of energy applied to the sealant. The press may include a displacement transducer that detects a pre-pressed thickness of the insulating glass unit. The measured pre-pressed thickness is used to automatically select a press thickness from a set of pressed IGU thicknesses.

Abstract: The furnace of the facility includes partitions in which hot gases from the baking of carbonaceous blocks circulate, and heating ramps (21, 22, 23) revolving in relation to the furnace, equipped with burners or fuel injectors. Gas circulation lines (24) are defined along the partitions between an air blowing leg (20) and a corresponding gas suction leg (12). To detect even partial partition blocking of a partition, the process includes, on a continuous basis: a. for each gas circulation line, continuous recording of at least one of the following measured parameters: temperature, pressure, flow, oxygen concentration and carbon monoxide concentration; b. evaluation of at least one factor from the measured parameters; c. comparison of this factor with a corresponding reference value; d. emission of a malfunctioning signal when the comparison between the factor and the corresponding reference value does not meet with the predefined safety criteria.

Abstract: In a melting furnace, a vibration inducer is installed on a furnace vessel, a sensor is arranged opposite or at another place on the furnace vessel and a signal recording and calculation unit is connected to the vibration inducer and the sensor. The melting process can be monitored and the progress of melting can be measured by measuring the signals of the vibration inducement after having passed through the interior of the furnace by this sensor and evaluating the signals of the signal recording and calculation unit. Thus, process-controlled, state-oriented regulation of the melting process can be carried out and the electric arc power is optimally matched to the respective state of the melting process. The signal of the sensor is preferably correlated with the excitation signal of the vibration inducer and/or conclusions are drawn about the melting process by combined evaluation of the vibration inducement and the measured vibration.

Abstract: According to one embodiment, an decoloring apparatus includes: an decoloring processing unit configured to apply decoloring processing decoloring a color of an decolorable colorant; a sheet conveying unit configured to convey the sheet and cause the sheet to pass through the decoloring processing unit; an image reading unit arranged further on an upstream side than the decoloring processing unit in a sheet conveying direction by the sheet conveying unit and configured to read the image formed on the sheet conveyed by the sheet conveying unit; a thickness sensor arranged further on the upstream side than the decoloring processing unit in the sheet conveying direction by the sheet conveying unit and configured to detect thickness of the sheet conveyed by the sheet conveying unit; an decolorability determining unit configured to determine, on the basis of a detection result in at least one of the image reading unit and the thickness sensor, executability of the decoloring processing in the decoloring processing

Abstract: Disclosed is an exemplary surgical system employing a temperature controlled docking station. The surgical system may include an articulating arm that is selectively moveable within a range of positions. A tray for receiving items used in performing a procedure may be attached to the articulating arm. The docking station may be attached to the tray. The docking station may include a heating element for selectively heating the docking station, a temperature sensor for monitoring a temperature of the docking station, and a reader configured for collecting information associated with an article placed in the docking station. The surgical system may also include a controller operably connected to the heating element, the temperature sensor, and the reader. The controller may be configured to adjust a heat output of the heating element in response to a signal received from the temperature sensor and/or the reader.