Abstract: A conveyor bowl for a vibratory conveyor device includes a main body made of stainless steel and manufactured by primary shaping. The main body has an interface section for coupling to a vibration unit, and a conveyor section for conveying conveyed parts. The main body may be designed as a cast part. The main body may be a precision cast part or an investment cast part. The main body may be made of austenite. The interface section and the conveyor section may be formed in one piece or formed integrally with the main body.

Abstract: A conveyor bowl for a vibratory conveyor device includes a main body made of stainless steel and manufactured by primary shaping. The main body has an interface section for coupling to a vibration unit, and a conveyor section for conveying conveyed parts. The main body may be designed as a cast part. The main body may be a precision cast part or an investment cast part. The main body may be made of austenite. The interface section and the conveyor section may be formed in one piece or formed integrally with the main body.

Abstract: A measuring method for measuring physical variables comprises the selection of a working point (AP) lying within a total measurement range (G) of a physical variable (M) to measured, the detection of a measured value (M(t1)) of the physical variable at a first measuring time (t1), the determination of a displacement value (V(t1)) as the result of a subtraction of the measures value (M(t1)) measured at the first measuring time from the working point (AP), the formation of change values (C(t2), C(t3) . . . C(tx)) of the physical variable (M) by acquiring subsequent measured values (M(t2), M(t3) . . . M(tx)) of the physical variable at subsequent measuring times (t2, t3 . . . tx) and addition of the displacement value (V(t1)) to the subsequent measured values.

Abstract: A measuring method for measuring physical variables comprises the selection of a working point (AP) lying within a total measurement range (G) of a physical variable (M) to be measured, the detection of a measured value (M(t1)) of the physical variable at a first measuring time (t1), the determination of a displacement value (V(t1)) as the result of a subtraction of the measured value (M(t1)) measured at the first measuring time from the working point (AP), the formation of change values (C(t2), C(t3) . . . C(tx)) of the physical variable (M) by acquiring subsequent measured values (M(t2), M(t3) . . . M(tx)) of the physical variable at subsequent measuring times (t2, t3 . . . tx) and addition of the displacement value (V(t1)) to the subsequent measured values.

Abstract: A measuring method for measuring physical variables comprises—the selection of a working point (AP) lying within a total measurement range (G) of a physical variable (M) to be measured,—the detection of a measured value (M(t1)) of the physical variable at a first measuring time (t1),—the determination of a displacement value (V(t1)) as the result of a subtraction of the measured value (M(t1)) measured at the first measuring time from the working point (AP),—the formation of change values (C(t2), C(t3) . . . C(tx)) of the physical variable (M) by acquiring subsequent measured values (M(t2), M(t3) . . . M(tx)) of the physical variable at subsequent measuring times (t2, t3 . . . tx) and addition of the displacement value (V(t1)) to the subsequent measured values.

Abstract: A measuring method for measuring physical variables comprises—the selection of a working point (AP) lying within a total measurement range (G) of a physical variable (M) to be measured,—the detection of a measured value (M(t1)) of the physical variable at a first measuring time (t1),—the determination of a displacement value (V(t1)) as the result of a subtraction of the measured value (M(t1)) measured at the first measuring time from the working point (AP),—the formation of change values (C(t2), C(t3) . . . C(tx)) of the physical variable (M) by acquiring subsequent measured values (M(t2), M(t3) . . . M(tx)) of the physical variable at subsequent measuring times (t2, t3 . . . tx) and addition of the displacement value (V(t1)) to the subsequent measured values.

Abstract: In a data carrier (1) and in an integrated circuit (5), a first signal processing circuit (8) with a signal-independent power supply is provided for processing a signal stream (SF1) in accordance with a first transmission protocol, and a second signal processing circuit (9) with a signal-dependent power supply is provided for processing a signal stream (SF2) in accordance with a second transmission protocol, which signal stream (SF2) in accordance with the second transmission protocol comprises a signal characteristic, namely a lead signal (VLS), and a detection circuit (25) is provided, which detection circuit is designed for detecting the lead signal (VLS) and ensuring the supplying of the second signal processing circuit (9) with power from a power source (14) provided for the second signal processing circuit (9) following a recognition of the occurrence of the lead signal (VLS).

Abstract: In a data carrier (1) and in an integrated circuit (5), a first signal processing circuit (8) with a signal-independent power supply is provided for processing a signal stream (SF1) in accordance with a first transmission protocol, and a second signal processing circuit (9) with a signal-dependent power supply is provided for processing a signal stream (SF2) in accordance with a second transmission protocol, which signal stream (SF2) in accordance with the second transmission protocol comprises a signal characteristic, namely a lead signal (VLS), and a detection circuit (25) is provided, which detection circuit is designed for detecting the lead signal (VLS) and ensuring the supplying of the second signal processing circuit (9) with power from a power source (14) provided for the second signal processing circuit (9) following a recognition of the occurrence of the lead signal (VLS).