A sensor may include a housing configured to couple to a machine; at least one processor within the housing; a battery within the housing; a communication adapter within the housing and coupled to the at least one processor; and a measurement device within the housing and coupled to the at least one processor and the battery. The communication adapter may be configured to wirelessly connect to a communication network. The measurement device may be configured to: obtain measurements of a physical characteristic of the machine to which the housing is coupled and transmit the measurements via the communication adapter, and automatically switch between a first measurement mode comprising a first sampling rate and a second measurement mode comprising a second sampling rate, different from the first sampling rate, without human intervention.

A sensor may include a housing configured to couple to a machine; at least one processor within the housing; a battery within the housing; a communication adapter within the housing and coupled to the at least one processor; and a measurement device within the housing and coupled to the at least one processor and the battery. The communication adapter may be configured to wirelessly connect to a communication network. The measurement device may be configured to: obtain measurements of a physical characteristic of the machine to which the housing is coupled and transmit the measurements via the communication adapter, and automatically switch between a first measurement mode comprising a first sampling rate and a second measurement mode comprising a second sampling rate, different from the first sampling rate, without human intervention.

A fish strike notification device includes a detection signal acquisition unit, a vibration generator and a vibration instructor. The detection signal acquisition unit is configured to acquire a detection signal that is output from a sensor configured to detect vibration generated by at least one detection target that includes a fishing reel and a fishing rod. The vibration generator is attachable to a user and configured to generate vibrations. The vibration instructor is configured to output a vibration instruction signal to cause the vibration generator to generate the vibrations based on the detection signal acquired by the detection signal acquisition unit.

A method for detecting an oscillation of a vehicle part for a vehicle contains a step for applying an electric excitation signal to at least one electric coil. The at least one electric coil is inductively coupled to at least one position element. The at least one position element is coupled to the vehicle part. The method also contains a step for inputting an electric coil signal from the at least one electric coil. The electric coil signal is tapped at the at least one coil in response to the electric excitation signal and affected by the at least one position element. The method also contains a step for determining at least one property of the oscillation of the vehicle part based on the input electric coil signal.

Embodiments of the present disclosure relate to the field of intelligent devices. The present disclosure provides a method for monitoring motor vibration, a terminal device, and a computer readable storage medium. In the method, vibration data of the motor is acquired in real time when it is detected that a motor is vibrating; the vibration data is converted into image data indicating a vibration sensation; and the image data is displayed. In this way, the strength of motor vibration is visualized, and the distinguishability of tactile perception is improved.

Embodiments of the present disclosure relate to the field of intelligent devices. The present disclosure provides a method for monitoring motor vibration, a terminal device, and a computer readable storage medium. In the method, vibration data of the motor is acquired in real time when it is detected that a motor is vibrating; the vibration data is converted into image data indicating a vibration sensation; and the image data is displayed. In this way, the strength of motor vibration is visualized, and the distinguishability of tactile perception is improved.

A wearable sensing device includes clothing worn by a user, and a sensor unit including a sensor and being attached to the clothing. The sensor unit includes: a body; first and second bracket parts provided to sandwich the body and fixed to the clothing; and first and second hinge parts respectively coupling the body and first and second bracket parts. The first and second bracket parts of the sensor unit are respectively attached to first and second sensor attachment parts provided on clothing 22L.

The invention provides a nozzle (2) for abrasive waterjet cutting. The nozzle (2) comprises: a body (4) comprising an outer surface (6); a passage (8) through the body, said passage comprising: in inlet section, an outlet section and a passage direction (14), said passage being configured for guiding an abrasive waterjet. A resistive strain gauge sensor (20) comprises a sensitivity direction (22) along the passage direction. The outer surface is circular and presents a planar area (40) for the sensor which is connected by a Wheatstone bridge. The invention also provides an abrasive waterjet nozzle manufacturing method. The invention also provides a use of a strain gauge sensor attached to a nozzle for abrasive waterjet cutting, for measuring bending vibrations.

The three-dimensional standard vibrator based on the aerostatic gas-floating decoupling device contains a base. The base is installed with a X axis vibrator, a X axis return mechanism, a Y axis vibrator, a Y axis return mechanism, a Z axis vibrator, and a three-dimensional vibration platform. The X axis vibrator and the X axis return mechanism are both installed along X axis but separated by the three-dimensional vibration platform. The Y axis vibrator and the Y axis return mechanism are both installed along Y axis but also separated by the three-dimensional vibration platform. There are two aerostatic gas-floating plates corresponding to the vibrator and connecting to the X axis and Y axis vibrators, respectively. Two intervals used to generate gas films are formed between the two aerostatic gas-floating plates and the three-dimensional vibrator, respectively. The X axis and Y axis return mechanisms both consist of a reset spring and an aerostatic gas-floating plate corresponding to the spring. The Z axis vibrator is connected with the Z axis aerostatic gas-floating decoupling device. There are intervals used to form gas films between the Z axis aerostatic gas-floating decoupling device and the three-dimensional vibration platform. The present invention contains the advantages of high loading capacity, supporting stability and uniformity.

A test fixture for securing a test article is disclosed. The test fixture includes a frame, an upper grip, at least one heat shield, a cooling assembly, and insulation. The frame defines an upper portion and a lower portion. The lower portion of the frame is releasably mounted to a vibration device. The upper grip is connected to the upper portion of the frame and the lower grip is connected to the lower portion of the frame. The heat shield is positioned to insulate at least one of the upper grip and the lower grip. The upper grip is configured to secure an upper portion of the test article along an upper interface. The lower grip is configured to secure a lower portion of the test article along a lower interface. The cooling assembly transports a cooling medium across at least one of the upper interface and the lower interface.