子分类:
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 161 | Thermally compensated fluorescence decay rate temperature sensor and method of use | US11161657 | 2005-08-11 | US07104683B2 | 2006-09-12 | Nicholas Djeu |
| The present invention provides a thermally compensated fluorescence decay rate temperature sensor capable of measuring the true temperature of a sample surface and its associated method of use. | ||||||
| 162 | Method and system for conservative evaluation, validation and monitoring of thermal processing | US11301933 | 2005-12-13 | US20060133449A1 | 2006-06-22 | Josip Simunovic; Kenneth Swartzel; Eric Adles |
| A method of generating a temperature measurement for a batch or a continuous stream of material. The method includes providing a particle having a signal that changes at a pre-determined temperature; inserting the particle into the batch or continuous stream; and detecting a signal change from the particle to thereby generate a temperature measurement for the batch or continuous stream. A suitable system for use in carrying out the method is also described. | ||||||
| 163 | Battery operated warning sensor | US10657500 | 2003-09-08 | US07012535B2 | 2006-03-14 | John Keller |
| An alarm device for signaling when an object reaches a specified condition. The alarm device includes a sensor for detecting the condition of the object. The device further includes a switch element which is closed when the sensor indicates the specified condition. The closed switch element triggers an alarm which will signal a person monitoring the condition that the specified condition has been reached. | ||||||
| 164 | Method and system for conservative evaluation, validation and monitoring of thermal processing | US10855118 | 2004-05-27 | US07004620B2 | 2006-02-28 | Josip Simunovic; Kenneth R. Swartzel; Eric Adles |
| A method of generating a temperature measurement for a batch or a continuous stream of material. The method includes providing a particle having a signal that changes at a pre-determined temperature; inserting the particle into the batch or continuous stream; and detecting a signal change from the particle to thereby generate a temperature measurement for the batch or continuous stream. A suitable system for use in carrying out the method is also described. | ||||||
| 165 | Method and system to represent a temperature experienced by a medical device in a medical washing machine | US10613276 | 2003-07-03 | US20050000548A1 | 2005-01-06 | Mark Basile; Ralph Basile; Steven Basile |
| A method and system to represent surface temperatures. The method and system represent a surface temperature experienced by a medical device during a washing cycle in a medical washing machine. A temperature strip is positioned proximate a surface of the medical device to represent the surface temperature experienced by the medical device during the washing cycle in the medical washing machine. | ||||||
| 166 | Method and system for conservative evaluation, validation and monitoring of thermal processing | US09804366 | 2001-03-12 | US06776523B2 | 2004-08-17 | Josip Simunovic; Kenneth R. Swartzel; Eric Adles |
| A method of generating a temperature measurement for a batch or a continuous stream of material. The method includes providing a particle having a signal that changes at a pre-determined temperature; inserting the particle into the batch or continuous stream; and detecting a signal change from the particle to thereby generate a temperature measurement for the batch or continuous stream. A suitable system for use in carrying out the method is also described. | ||||||
| 167 | Ganged fire extinguisher system | US10686830 | 2003-10-16 | US20040134671A1 | 2004-07-15 | Larry W. Akins; Walter Liskowski |
| A non-electrically actuated ganged fire extinguisher system for use in an enclosure of a size larger than the capacity of a single pre-engineered fire extinguisher comprises at least two pre-engineered fire extinguishers positioned at spaced locations in the enclosure. An actuation valve is mounted on the outlet of each fire extinguisher. A fluid operated valve actuator for each valve retains the valve in a closed state when the actuator is pressurized and opens the valve when the actuator is depressurized. A vent line connects the valve actuators and provides fluid communication therebetween, such that the actuators are maintained at the same pressure state. At least one non-electrical temperature sensor is mounted in fluid communication with the vent line. The temperature sensor opens an outlet to the vent line and releases the pressure therein when the temperature in the vicinity of the sensor reaches a predetermined value indicative of a fire hazard. The release of pressure in the vent line in turn causes substantially simultaneous actuation of all fire extinguishers connected to the vent line. | ||||||
| 168 | Temperature activated systems | US10744768 | 2003-12-22 | US20040134412A1 | 2004-07-15 | Dennis N. Petrakis |
| A shape memory material activated device of the present invention uses a shape memory material activator to create a path through a shell wall of the device. The path through the shell wall may release a substance contained in the shell or allow a substance to enter the shell. The path may be created by fracturing, puncturing, exploding, imploding, peeling, tearing, stretching, separating, debonding or otherwise opening the shell. The devices according to the present invention may be used as temperature sensors or warning devices, drug delivery devices, and the like. | ||||||
| 169 | Battery operated warning sensor | US10657500 | 2003-09-08 | US20040066304A1 | 2004-04-08 | John Keller |
| An alarm device for signaling when an object reaches a specified condition. The alarm device includes a sensor for detecting the condition of the object. The device further includes a switch element which is closed when the sensor indicates the specified condition. The closed switch element triggers an alarm which will signal a person monitoring the condition that the specified condition has been reached. | ||||||
| 170 | Temperature activated systems | US09815643 | 2001-03-23 | US06682521B2 | 2004-01-27 | Dennis N. Petrakis |
| A shape memory material activated device of the present invention uses a shape memory material activator to create a path through a shell wall of the device. The path through the shell wall may release a substance contained in the shell or allow a substance to enter the shell. The path may be created by fracturing, puncturing, exploding, imploding, peeling, tearing, stretching, separating, debonding or otherwise opening the shell. The devices according to the present invention may be used as temperature sensors or warning devices, drug delivery devices, and the like. | ||||||
| 171 | Battery operated temperature warning sensor | US09966569 | 2001-09-26 | US20030058115A1 | 2003-03-27 | John Keller |
| An alarm device for signaling when an object reaches a specified temperature. The alarm device includes a thermometer for detecting the temperature of the object. The device further includes a switch element which is closed when the thermometer indicates the specified temperature. The closed switch element triggers an alarm, such as a light or a buzzer, which will signal a person monitoring the temperature that the specified temperature has been reached. | ||||||
| 172 | Generating temperature compensation profiles | US09366593 | 1999-08-03 | US06502047B1 | 2002-12-31 | Jack Chi-Chieh Wen |
| A system compensates for temperature for an electrical parameter of an electronic unit that comprises a plurality of electronic devices. The system determines a measure of the electrical parameter of one electronic device at a reference temperature. The system further receives a first temperature profile and a second temperature profile and causes the first temperature profile and the second temperature profile to intersect at the reference temperature. The system then generates a combined temperature profile by combining the first temperature profile at temperatures below the reference temperature with the second temperature profile at temperatures above the reference temperature. | ||||||
| 173 | Temperature monitoring device | US09847276 | 2001-05-03 | US20010050617A1 | 2001-12-13 | Sture Ostling; Uno Axelsson |
| Temperature monitoring device for monitoring or controlling the temperature of an object, and preferably indicating and/or recording abnormal temperature variations of the object includes a housing having a contact portion for contacting the object, a sensing member in heat transferring contact with the contact portion for emitting signals representative of the object temperature, a control device that receives signals from the sensing member and actuates an indicator, a power source connectable to the sensing member, the control device and the indicator, and a switch biased to interrupt the power supply to the sensing member, control device and indicator. A portion of the housing is movable between a first position where the switch interrupts the power supply and a second position in which the housing portion urges the switch to the power supply position. | ||||||
| 174 | Apparatus for preparing a hot beverage | US612140 | 1996-03-07 | US5649471A | 1997-07-22 | Ingrid E. J. R. Heynderickx; Antonius A. J. Rademaker |
| An apparatus is provided (1) for preparing a hot beverage, comprising a water reservoir (3), means for removing and heating water from the reservoir and transferring it into a brewing chamber (5), and a light-transmissive jug (9) for catching hot liquid emerging from the brewing chamber (5), a wall (13) of the jug (9) being provided with optical means (15) for indicating the volume of liquid contained in the jug (9), wherein the optical means (15) comprise a first graduated scale (159) and a second graduated scale (153), the first scale (159) being clearly visible only when the jug wall temperature is below a reference temperature T.sub.o and the second scale (153) being clearly visible only when the jug wall temperature is above the reference temperature T.sub.o, whereby the reference temperature T.sub.o is within the range of 25.degree. C.<T.sub.o <80.degree. C., the ratio of the pitch of graduations in the second scale (153) to the pitch of corresponding graduations in the first scale (159) being approximately equal to the liquid yield ratio (R.sub.L) of the apparatus. In practice, the optical means (15) may comprise a film (155) of polymer-dispersed liquid crystalline (PDLC) material disposed between the first (159) and second (153) graduated scales. | ||||||
| 175 | Temperature warning device | US814792 | 1991-12-31 | US5203278A | 1993-04-20 | Richard J. Kinney |
| A temperature warning device for indicating when a threshold temperature has been exceeded includes a threaded bolt having a bolt head and a bolt body. The bolt head and bolt body have a longitudinal bore defined by a surrounding surface with the bore having a closed end and an open end at the bolt head. A plunger in the bore has a plunger head and a plunger body terminating at the open end of the bore. A retaining cap is secured in the bore of the bolt head and has a cap hole through which the plunger body freely extends. A sleeve of a fusible material is contained in the bore which melts at the threshold temperature. This sleeve substantially fills a volume of the bore radially between the plunger body and the surrounding surface of the bore and longitudinally between the plunger head and the cap. A compressed spring is located in the bore between the closed end and the plunger head. With this construction, if the threshold temperature is exceeded, the fusible sleeve melts and the spring moves the plunger longitudinally so that the plunger body extends beyond the retaining cap and the bolt head and is easily visible to serve as a warning. A two stage signalling is achieved by forming the sleeve of two discrete longitudinal portions butted end to end with a fusible material of the portion adjacent the plunger head having a lower melting temperature than the other the portion. | ||||||
| 176 | Method and apparatus for indirectly measuring a solid-liquid interface equilibrium temperature | US230698 | 1988-08-09 | US4842417A | 1989-06-27 | Odd A. Asbjornsen |
| A method and apparatus for indirectly measuring the solid-liquid interface equilibrium temperature dynamically excites the heat flux flowing through a coldfinger arrangement followed by a statistical estimation of the interface temperature, solid layer heat conductivity and thickness ratio, bulk liquid temperature and thermal heat transfer coefficient. The coldfinger includes a pair of substantially concentric and substantially cylindrical members arranged one within another so as to have an outer member and a venturi-shaped inner member and a space therebetween. The members are arranged such that a gas flows through the inner member and a space between the inner and outer members of the coldfinger and then exits the coldfinger arrangement. The average gas temperature within the space of the coldfinger and the difference in temperature between the gas entering the coldfinger and the gas exiting the coldfinger are measured and the heat flux flowing through the coldfinger is varied in a time varying fashion either by varying the amount of heat supplied to the gas entering the coldfinger or by varying the amount of gas flowing through the coldfinger. The solid-liquid interface equilibrium temperature is determined on the basis of the respective measured temperatures and the specific parameters of the gas and the solid and the liquid and the gas flowrate and the dimensions of the coldfinger. | ||||||
| 177 | Composition having regulated occurence of opacity and clarity at selected temperatures and method of making the same and also use of the composition | US873290 | 1986-06-05 | US4743557A | 1988-05-10 | Maj-Britt I. Tiru; Mandayam O. Tiru |
| A composition having regulated occurrence of opacity and clarity at selected temperatures; method of making and using such a composition to create a temperature-indicating device by filling the composition in a suitable container of transparent material and having a background in the form of a color, a letter or a number i.e., in order to be able to visually interpret the difference between opacity and clarity. A reversible indicating device is made which can show if the upper or lower limits of a pre-set temperature interval has been exceeded or fallen below. | ||||||
| 178 | Monitoring temperature within a vessel | US731035 | 1985-05-06 | US4681729A | 1987-07-21 | Eric Pendleton; Karl A. Roberts; Alan Murray |
| A vessel for the storage and monitoring of nuclear fuel materials incorporates a device (12) within its interior for providing an externally detectable signal indicating whether any temperature rise has occurred. The device (12) comprises a magnet (32) attracted towards a boundary wall (11) of the vessel and maintained in that position by a temperature-sensitive element such as a thermal link (38). The magnet (32) is subjected to an oppositely directed force by a spring (30), which is effective to drive the magnet (32) away from the wall (11) in the event of a substantial temperature rise within the vessel thereby producing an externally detectable change in magnetic flux. | ||||||
| 179 | Temperature sensor for cables | US629256 | 1984-07-09 | US4610552A | 1986-09-09 | Satoru Kobayashi; Yoshiaki Sato; Haruo Imaizumi |
| A temperature sensor is provided comprising a conductor having a low-melting-point, a fibrous insulating layer adjacent the low-melting-point conductor and separating it from a second conductor. An oscillator applying a pulse signal to the sensor and a receiver receiving the pulse signal through the sensor can detect changes in the signal wave form due to melting or distortion of the low-melting-point conductor. The specific temperature to be sensed can be preset by providing preheating of the sensor, as by Joule heating, by passing a current through the low-melting-point conductor. | ||||||
| 180 | Electronic clinical thermometer, and method of measuring body temperature | US561181 | 1983-12-14 | US4574359A | 1986-03-04 | Hideo Ishizaka; Yoshiki Hanzawa |
| An electronic clinical thermometer successively stores the temperature detected at a portion of a body, measures the time which has elapsed since start of measurement, and reads the detected temperature, corresponding to a prescribed length of past time, out of a storage to obtain a mean value during the length of past time. The thermometer repeats, at a predetermined period, a process of obtaining and displaying a predicted value of a stable temperature from the mean detected temperature and elapsed measurement time on the basis of a stable temperature prediction function in which measurement time is a variable, the temperature prediction function defining a temperature change up to a final, stable temperature. The prediction computation is halted when, after the elapsed measurement time has exceeded a prescribed magnitude and a difference exhibited by the mean detected temperature corresponding to two points in time no longer shows an increase outside a prescribed range, the detected mean temperature corresponding to a present point in time exhibits a decrease outside a prescribed range in being compared with the mean detected temperature at the preceding point in time. | ||||||
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