The invention relates to a piezoelectric force sensor (1) comprising a housing (10) having at least one piezoelectric body (11) and an electrode (12) electrically connected to said body (11), wherein a connection device (13) for forwarding measurement signals having a contact pin (131) is fastened or molded on the housing (10). The contact pin (131) is connected to the electrode (12) in an electrically conductive manner. According to the invention, a helical compression spring (14) is electrically conductively connected to the contact pin (131) as an electrical connection within the piezoelectric force sensor (1). For this purpose, the helical compression spring (14) is removably electrically conductively connected to the electrode (12) in an operative manner so that the contact pin (131) has a spatial clearance from the electrode (12) and measurement signals from the electrode (12) can be extracted from the housing (10) of the piezoelectric force sensor (1) via the helical compression spring (14) and the connected contact pin (131) and can be picked up on the connection device (13).

An electromagnetic coupling sensing device includes a frequency generation module, a first resonant module, a second resonant module, and an echo acquisition and processing module. The first resonant module generates a primary resonant signal based on the frequency setting signal generated by the frequency generation module. The second resonant module couples with the first resonant module through a coupling capacitance to generate a secondary resonant signal based on the primary resonance signal. The second resonant module includes a coil. A ferrite is provided in the coil and a height of the coil is higher than the ferrite. The coil is capable of carrying a weight to be measured to deform such that an intrinsic frequency of the electromagnetic coupling sensing device changes. The echo acquisition and processing module collects the secondary resonant signal and outputs a voltage signal changing according to the intrinsic frequency.

A force sensor unit having a simple structure to allow ready assembling and easy downsizing of the force sensor unit. The force sensor unit includes a cylindrical body, a substrate that blocks one end of the cylindrical body, a force sensor that is supported on the substrate, and a force transmission mechanism that is disposed in an internal space of the cylindrical body to transmit a force to the force sensor. The force transmission mechanism includes a contact member, a coil spring, and an operated member. These members are arranged in order in the internal space of the cylindrical body, and are not adhered to nor engaged with each other. The members except the substrate are simply fitted loosely in the internal space of the cylindrical body, thereby facilitating assembling of the force sensor unit and enabling downsizing of the force sensor unit.

The present disclosure relates to a force measuring device (1) comprising a spring module (2), and an electronic module (3), detachably mechanically connected to the spring module. The spring module comprises a test head (21) defining an outer surface of the device, a spring seat (23), and a spring (24) arranged between the test head and the spring seat, with a first end (24a) of the spring engaging the test head and a second end (24b) of the spring engaging the spring seat. The electronic module comprises a force sensor (31) arranged in physical contact with the spring seat.

An over-pressure indicator, including a cup-shaped body having, on its bottom, a hole inside which is sealably housed a mobile element loaded by a spring towards the bottom of the cup-shaped body, the mobile element facing an indicator sensitive part for communication with an area where pressure verification is wanted. The mobile element coupled with a signaller of a movement thereof. The spring pressed by a pre-loading ring nut screwed onto the cup-shaped body. The nut torsionally removably coupled with a calibration cap of the indicator. The calibration cap having at least one stop that, when it abuts against a portion of the cup-shaped body, limits further screwing of the nut thus determining pressure beyond which mobile element movement is allowed. The movement causing intervention of the indicator so by coupling the suitable calibration cap and indicator and screwing it in fully, setting the indicator intervention pressure is possible.

A method of monitoring lateral force of a coil spring having a body and opposing end coils is disclosed. A fixture includes a base defining a planar surface with a shaft that extends from said planar surface at a normal angle to said planar surface. An axis defined by the coil spring is aligned with the shaft. Angular displacement from the shaft of an end coil is measured, and the angular displacement is correlated with a lateral force value.

A device and system for monitoring a load or applied force includes a body having first and second ends, a plate, a force-providing member connected to the plate, a first biasing member, and a first sensor. In embodiments the first biasing member is disposed between a portion of the body at or about the first end and a portion of the plate, and is configured to substantially retain the plate in an initial position during normal operation of the device; the first sensor is configured to sense a displacement (e.g., displacement position) with respect to the plate; and the body includes a portion configured to connect to or apply a force to another component. A controller may selectively instruct and/or operate a component, such as a motor, in response to an output generated or provided by the sensor. If an excessive force is sensed, the device may mitigate resulting damage.