Class / Patent application number | Description | Number of patent applications / Date published |
073514050 | Fluid or fluent material | 17 |
20120137777 | Acceleration sensor and/or tilt sensor - Acceleration and/or tilt sensor having a ferromagnetic fluid that is located in a receptacle, and the receptacle constitutes a neutral position for the fluid, and the fluid is permanently magnetized, and a magnetic field detector arrangement is located at the receptacle to detect a displacement of the fluid, wherein a portion of the fluid can be displaced relative to the receptacle from the neutral position to an operating position by an external force while maintaining a continuous surface with the portion of the fluid remaining in the neutral position, and the fluid returns to the neutral position after removal of the external force. | 06-07-2012 |
20140238130 | ACCELEROMETER - The accelerometer of the present application includes: a main body; a channel positioned in the main body and forming a predetermined movement space; a conductive droplet positioned in the movement space and moving in the movement space according to inertia; a conduction section correspondingly positioned to the movement space and coming in contact with the conductive droplet; and a resistance measurement section connected to the conduction section and measuring the electric resistance of the conduction section. | 08-28-2014 |
073514090 | Fluid or fluent inertial mass | 11 |
20080216571 | Convective Accelerometer with "Positive' or "Negative" Inertial Mass - This invention relates to high precision, fluid-containing, transducer-based accelerometers that are capable of measuring acceleration, inclination, position and velocity by measuring the electronic response of a transducer to fluid flow caused by external acceleration or by free convection. The accelerometers of this invention are capable of varying the local density of the fluid, thereby creating a volume of fluid with a lower or higher density compared to the rest of the fluid in the accelerometer. The movement of this volume of lower or higher density fluid as a result of external acceleration is measured to determine the external acceleration. | 09-11-2008 |
20090139329 | Liquid seal sensor - To provide a small-sized liquid seal sensor that can enhance degrees of freedom in detection directions. A liquid seal sensor having a liquid seal part that seals a liquid therein, and a detecting part that detects changes in the liquid sealed in the liquid seal part has a configuration in which the detecting part detects changes in the liquid sealed in the liquid seal part, and thus when an acceleration is applied, the detecting part detects changes in the liquid sealed in the liquid seal part, whereby the sensitivity to accelerations can be enhanced in any directions. | 06-04-2009 |
20090145226 | Heater controller having improved start-up for thermal sensor - A closed-loop heater control circuit for use with integrated circuit thermal sensing devices, such as thermal accelerometers, is disclosed. The heater control circuit includes a switched-capacitor integrating circuit and a controller or modulator. The switched-capacitor integrating unit integrates a common-mode voltage signal from an instrument amplifier with respect to an analog common reference voltage. In operation, the switched-capacitor integrating unit is adapted so that the closed-loop is opened briefly at the beginning of every new cycle, e.g., using an enable signal, during fast start-up or power-down. | 06-11-2009 |
20100024550 | INERTIAL MEASUREMENT UNIT WITH GAS PLENUMS - An inertial measurement unit comprises a mounting plate with an opening therethrough, and a sensor assembly disposed in the opening of the mounting plate. Upper and lower support shells having shell flanges are attached to upper and lower surfaces of the mounting plate. The upper and lower support shells surround the sensor assembly. A plurality of gas bearing pads each extends through apertures in the upper and lower support shells. Upper and lower gas plenums have plenum flanges attached to the shell flanges of the upper and lower support shells, with the upper and lower gas plenums surrounding the upper and lower support shells. Pressure relief valves are coupled to the plenum flanges of the upper and lower gas plenums. The gas bearing pads and the sensor assembly are separated by a gap when pressurized gas is fed into the upper and lower gas plenums, thereby creating a gas bearing that allows the sensor assembly to be freely suspended and rotated in all directions. | 02-04-2010 |
20110100124 | MOUNTED SHOCK SENSOR - This application is directed to a shock sensor mounted in an electronic device. The shock sensor includes both active and passive shock detection methods that allow a technician to determine whether the electronic device was subjected to a shock event that exceeded an impact threshold level. The shock sensor may include shock detection contacts that form an electrical circuit that remains open in the absence of a shock event that exceeds an impact threshold level. In response to a significant shock event, a movable component or substance of the shock sensor may move from a first position to a second position, thereby closing the electrical circuit formed by the shock detection contacts. The change in circuit may be detected and used to provide active indication of whether the electronic device has been subjected to a substantial shock event. In addition, the shock sensor may be observed to passively determine whether the electronic device has been subjected to a substantial shock event. | 05-05-2011 |
20130133425 | THERMAL CONVECTION-TYPE ACCELEROMETER - A thermal convection-type accelerometer includes a first insulating substrate, a circuit formed on the first insulating substrate, a first acceleration-sensing device coupled with the circuit, and a first supporting layer attached on the insulating substrate. The first acceleration-sensing device includes two temperature-sensing components and a heater disposed between the temperature-sensing components. The temperature-sensing components and the heater are directly formed on the first supporting layer. | 05-30-2013 |
20130327145 | ATOMIC FAR-OFF RESONANCE TRAP (FORT) ACCELEROMETER SYSTEM - One embodiment includes an accelerometer system. The accelerometer system can include a Far-Off Resonance Trap (FORT) control system configured to generate an optical trapping beam. The system can also include a FORT accelerometer detection system including a FORT that is configured to trap a cluster of atoms based on the optical trapping beam. The FORT accelerometer detection system can also include an interrogation system configured to determine motion of the cluster of atoms along at least one axis resulting from an external acceleration in the at least one axis based on a relative phase shift of an optical probe beam through the cluster of atoms. The system can further include an acceleration processor configured to calculate the external acceleration in the at least one axis based on the relative phase shift of the optical probe beam. | 12-12-2013 |
20140007684 | THERMAL CONVECTION TYPE ANGULAR ACCELEROMETER - A thermal convection type angular accelerometer includes an insulating substrate and an angular acceleration sensing device. The angular acceleration sensing device is disposed on the insulating substrate. The angular acceleration sensing device is configured to measure an angular acceleration of a rotation axis. The angular acceleration sensing device comprises a sensing group. The sensing group comprises two temperature sensing members and a heater disposed between the two temperature sensing members. The distance between two ends of the two temperature sensing members near the rotation axis is greater than the distance between the other two ends of the two temperature sensing members that are farther from the rotation axis. | 01-09-2014 |
20140123755 | MOTION SENSING - Technologies are generally described for detecting acceleration by sensing a movement of a liquid contained in at least one liquid flow path arranged in a film-type material. An example device may be configured to detect acceleration based at least in part on an output signal from at least one strain sensor formed on at least one surface of a film layer. The film layer may include at least one liquid flow path containing a liquid and arranged in the film layer. The strain sensor may be formed on the at least one surface of the film layer in the vicinity of the least one liquid flow path, and may be configured to detect deformation on the at least one surface of the film layer. | 05-08-2014 |
20140360267 | THERMAL CONVECTION TYPE LINEAR ACCELEROMETER - A thermal convection type linear accelerometer includes a substrate and a first sensing device. The first sensing device includes two first temperature-sensing components and a first heater. The two first temperature-sensing components are disposed on the substrate. The first heater is disposed on the substrate. The first heater is located between the two first temperature-sensing components. The two first temperature-sensing components are higher than the first heater relative to the substrate. | 12-11-2014 |
20160125780 | SENSORS EMPLOYING CONTROL SYSTEMS DETERMINING LOCATIONS OF MOVABLE DROPLETS WITHIN PASSAGEWAYS, AND RELATED METHODS - Sensors employing control systems determining locations of movable droplets within passageways, and related methods are disclosed. A sensor includes a movable droplet within a passageway supported on a substrate. The droplet may move to and from a quiescent point in the passageway which is at least partially formed by a hydrophobic layer. By including a hydrophobic layer having a hydrophobicity characteristic which decreases according to distance from the quiescent point, the droplet may move to a displacement position outside of the quiescent point in response to an external force. A control system of the sensor determines an acceleration and/or angular position of the sensor based on the displacement position. In this manner, a low cost sensor may be fabricated with without expensive nanostructures. | 05-05-2016 |
073514110 | Detection by fluid pressure | 3 |
20100281978 | INERTIAL SENSOR AND PRODUCING METHOD THEREOF - The present invention provides an inertial sensor and a producing method thereof. The inertial sensor measures the acceleration and angular acceleration of a moving object according to the sensed pressure difference (pressure gradient). The inertial sensor comprises a substrate; a circuit disposed on the substrate; a pressure device comprising an annular chamber that has a first end and a second end; a channel having a first end and a second end, with the second end being connected to the second end of the annular chamber; a pressure meter connected respectively to the first end of the annular chamber and the first end of the channel, wherein the pressure meter is electrically connected to the circuit; and a liquid filling the annular chamber. Hence, the present invention provides a highly sensitive planar inertial sensor, which simplifies the structure, makes easy the manufacturing process, and lowers the costs. The inertial sensor based on this invention can measure the acceleration and angular acceleration of a moving or rotating object, further allowing multi-axis measurements as a result of mutual integrations. | 11-11-2010 |
20120060605 | MEMS SENSOR CAPABLE OF SENSING ACCELERATION AND PRESSURE - A MEMS sensor capable of sensing acceleration and pressure includes a frame, a proof mass and flexible bridges connected between the frame and the proof mass in such a way that the proof mass is moveably suspended inside the frame. The proof mass is provided with a pressure sensing diaphragm and a sealed chamber corresponding to the diaphragm such that the proof mass is not only served as a moveable sensing element for acceleration measurement but also a pressure sensing element. | 03-15-2012 |
20130340525 | INTEGRATED INERTIAL SENSOR AND PRESSURE SENSOR, AND FORMING METHOD THEREFOR - An integrated inertial sensor and pressure sensor may include a first substrate including a first surface and a second surface; at least one or more conductive layers, formed on the first surface of the first substrate; a movable sensitive element, formed by using a first region of the first substrate; a second substrate and a third substrate, the second substrate being coupled to a surface of the conductive layer, the third substrate being coupled to the second surface of the first substrate in which the movable sensitive element of the inertial sensor is formed, and the third substrate and the second substrate are respectively arranged on opposite sides of the movable sensitive element; and a sensitive film of the pressure sensor, including at least a second region of the first substrate, or including at least one of the conductive layers on the second region of the first substrate. | 12-26-2013 |
073514120 | Fluid or fluent material dampening of an inertial element | 1 |
20110120220 | SENSOR AND METHOD FOR MOTION MEASUREMENT OF CO-EXISTING TILT AND HORIZONTAL ACCELERATION - A motion-sensing device for sensing tilt and acceleration when either tilt, horizontal acceleration, or tilt and horizontal acceleration acting concurrently, influence the device, including: a substrate having a vertical surface, a first accelerometer fixed to the vertical surface of the substrate; a pendulum flexibly coupled to the substrate proximate to the first accelerometer; and a second accelerometer fixed to the pendulum. The first and/or second accelerometers are preferably an accelerometer; a spring-mass system; and/or any tilt or accelerometer sensitive elements. The first accelerometer includes an accelerometer that measures tilt and linear acceleration in a first geometric plane, the pendulum is constrained to move in the first geometric plane, and the second accelerometer is operable to measure linear acceleration in the first geometric plane. The motion-sensing device or devices coupled to a machine, vehicle, and/or a control system. The pendulum is critically damped using a damping fluid. | 05-26-2011 |