A pneumatic tool has a hollowed main body. One end of the main body is assembled with a pneumatic motor having a transmission shaft inserted into the main body. The other end of the main body is assembled with a connecting member being slidable along an axial direction of the main body. One end of the connecting member forms a connecting portion, and the other end of the connecting member forms a knife assembling portion. A driving gear is rotatably assembled in the main body and engaged with the transmission shaft. A protruding post is assembled on a portion of the driving gear biasing from an axis of the driving gear. A linking bar has a first end and a second end opposite to the first end. The first end is pin-jointed to the protruding post, and the second end is pin-jointed to the connecting portion of the connecting member.

The machine for breaking a part of a tire down into pieces includes a frame and a tire support which is adapted to support a part of the tire. The machine also has a supplying device which is configured to feed the part of the tire to a cutting station which includes a cutting device. The cutting device has a first blade and a second blade that are pivotable with respect to one another at a fulcrum. At least one of the first and second blades has a concave shape and cooperates with the other blade to keep the part of the tire inside of the blades. The supplying device includes a movable unit which can pivot about a vertical axis between first and second positions.

The machine for breaking a part of a tire down into pieces includes a frame and a tire support which is adapted to support a part of the tire. The machine also has a supplying device which is configured to feed the part of the tire to a cutting station which includes a cutting device. The cutting device has a first blade and a second blade that are pivotable with respect to one another at a fulcrum. At least one of the first and second blades has a concave shape and cooperates with the other blade to keep the part of the tire inside of the blades. The supplying device includes a movable unit which can pivot about a vertical axis between first and second positions.

The present invention relates to a tube cutting knife monitoring system for a filling machine for manufacturing packages from a tube, the filling machine comprising a tube cutting knife (18) and a hydraulic system (20) adapted to actuate the tube cutting knife, wherein the monitoring system comprises: a pressure sensor (22) adapted to detect hydraulic pressure of the hydraulic system when the tube cutting knife is cutting the tube; and a logging system (26) adapted to log the hydraulic pressure detected by the pressure sensor.

The present invention relates to a tube cutting knife monitoring system for a filling machine for manufacturing packages from a tube, the filling machine comprising a tube cutting knife (18) and a hydraulic system (20) adapted to actuate the tube cutting knife, wherein the monitoring system comprises: a pressure sensor (22) adapted to detect hydraulic pressure of the hydraulic system when the tube cutting knife is cutting the tube; and a logging system (26) adapted to log the hydraulic pressure detected by the pressure sensor.

A shear cutting system for fibre tape taping machines in which the cutting of the fibre tape (1) is performed transversely with respect to the movement of the fibre tape (1) by shearing 5 between a cutting blade (2) and a counter blade (3) in an opposite relative movement between the cutting blade (2) and the counter blade (3), characterised in that it has orientation device for a blade support (4) of the cutting blade (2) configured for orienting the cutting blade (2) according to a cutting angle selected for cutting the fibre tape (1).

A shear cutting system for fibre tape taping machines in which the cutting of the fibre tape (1) is performed transversely with respect to the movement of the fibre tape (1) by shearing 5 between a cutting blade (2) and a counter blade (3) in an opposite relative movement between the cutting blade (2) and the counter blade (3), characterised in that it has orientation device for a blade support (4) of the cutting blade (2) configured for orienting the cutting blade (2) according to a cutting angle selected for cutting the fibre tape (1).

The invention relates to an automatic cutting device for printed graphic substrates. The device has a working plane configured to allow passage of a printed graphic substrate along a longitudinal direction (L) and a transverse cutting unit arranged at a slit of the working plane extending in a transverse direction (T) perpendicular to the longitudinal direction (L). The transverse cutting unit is movable along the slit in the transverse direction (T), and has a pair of uprights on which two pairs of counter-rotating blades are respectively mounted, the uprights being spaced apart in the longitudinal direction (L).

A steering control apparatus of an SBW system may include: a power motor configured to output a steering force in the SBW system; a power motor position sensor configured to sense an angular position of the power motor; a steering angle sensor configured to sense a steering angle of a steering wheel; a vehicle velocity sensor configured to sense a vehicle velocity; and a power motor control unit configured to calculate a target steering angle from the steering angle, and drive the power motor according to the target steering angle. The power motor control unit may calculate a feedback steering angle reflecting an output angle of a wheel, calculate a compensation steering angle for variably controlling the output angle of the wheel based on the feedback steering angle and the vehicle velocity, and corrects the target steering angle using the compensation steering angle.

A method of calculating a motor velocity in an electric power steering system comprises receiving a plurality of motor position signals from a motor position sensor of the electronic power steering system, calculating a plurality of angle difference based on the motor position signals prior to performing any filtering operations on the motor position signals, performing a linear regression analysis on the angle differences to predict an angle difference, and calculating a motor velocity based on the predicted angle difference.