An apparatus for emulating a variety of string instruments with a variety of configurations in order to measure the resulting, actual tension of a string on that instrument. The tension may be measured in real-time.

An apparatus for emulating a variety of string instruments with a variety of configurations in order to measure the resulting, actual tension of a string on that instrument. The tension may be measured in real-time.

Systems and methods of determining a tension of an anchor embedded in a dam are described. A dynamic impulse response of the dam is empirically obtained in such that a portion of the empirical dynamic impulse response is dominated by a dynamic behavior of the anchor. Furthermore, a set of modeled impulse responses that map to a set of tension values for the anchor are obtained. Next, a closest matching modeled impulse response from the set of modeled impulse responses that is a closest match to the portion of the empirical dynamic impulse response that is dominated by the dynamic behavior of the anchor is determined. Finally, a tension value from the set of tension values is selected, which is the closest match to the portion of the dynamic impulse response dominated by the dynamic behavior of the anchor. As such, the tension value of the anchor can be determined.

Systems and methods of determining a tension of an anchor embedded in a dam are described. A dynamic impulse response of the dam is empirically obtained in such that a portion of the empirical dynamic impulse response is dominated by a dynamic behavior of the anchor. Furthermore, a set of modeled impulse responses that map to a set of tension values for the anchor are obtained. Next, a closest matching modeled impulse response from the set of modeled impulse responses that is a closest match to the portion of the empirical dynamic impulse response that is dominated by the dynamic behavior of the anchor is determined. Finally, a tension value from the set of tension values is selected, which is the closest match to the portion of the dynamic impulse response dominated by the dynamic behavior of the anchor. As such, the tension value of the anchor can be determined.

The belt conveyor comprises: a conveyance belt (3) having at least one longitudinal segment (17) tensioned between first and second tension members; a device (21) for assessing the tension of said segment (17), laid out for assessing, in a determined measurement point located longitudinally between the first and second tension members, a deviation of the segment (17) relatively to a reference value, the deviation being taken along a determined measurement direction forming a non-zero angle with the longitudinal direction.

In the case of a method for detecting a tensile stress of a circumferential belt (5), this is deflected around a tension roller (4). In this way, the running length of the circumferential belt (5) is changed by adjusting the tension roller (4). A force measuring device (10) is provided, wherein the force measurement changes along with the adjustment path (6) of the tension roller (4). In order to make a reliable tensile stress detection possible, the sensitivities of the force measuring device (10) are determined with respect to the tensile stress for different points of the adjustment path. These sensitivities or calculated values are stored in a memory (32), which a controller (15) accesses. This calculates the tensile stress from the current adjustment path (6), the current bearing force and the stored sensitivities or values by means of interpolation.

In the case of a method for detecting a tensile stress of a circumferential belt (5), this is deflected around a tension roller (4). In this way, the running length of the circumferential belt (5) is changed by adjusting the tension roller (4). A force measuring device (10) is provided, wherein the force measurement changes along with the adjustment path (6) of the tension roller (4). In order to make a reliable tensile stress detection possible, the sensitivities of the force measuring device (10) are determined with respect to the tensile stress for different points of the adjustment path. These sensitivities or calculated values are stored in a memory (32), which a controller (15) accesses. This calculates the tensile stress from the current adjustment path (6), the current bearing force and the stored sensitivities or values by means of interpolation.

According to one aspect of the invention, an automated load testing tool suitable for use when field testing stretch film load containment forces is provided. According to a further aspect, the tool safely, reliably and accurately measures load containment forces in a time- and cost-effective manner, and ensures that operators cannot manipulate the test results. According to a still further aspect, the tool is used to accurately measure stretch film stiffness after application to a wrapped load. According to yet another aspect, the test unit is attached to a load that has already been wrapped with stretch film, and the unit automatically hooks and then pulls the film a predefined distance at a predefined rate so that the load force needed to displace the film is accurately measured.

An actuator having a nut (4) co-operating with a screw (2); a first cable (6) coupled to the nut and functionally connected to an output (16, 17, 22.4) of the actuator (100); and a motor (3) arranged to drive the screw (2) in rotation. The actuator also has a mechanism (92) for comparing the actual position of the nut relative to the frame (10) with a theoretical position for the nut relative to the frame (10) in order to obtain a position deviation (δang4, δlin4) of the nut; and a mechanism (93) for determining a force applied to the output (22.4) of the cable actuator (100) as a function of the position deviation of the nut. Also disclosed is a method of measuring a force applied to an output (16, 17, 24.1) of an actuator (100), and to a method of determining prior loading (t6,9) of a cable actuator (100).

An actuator having a nut (4) co-operating with a screw (2); a first cable (6) coupled to the nut and functionally connected to an output (16, 17, 22.4) of the actuator (100); and a motor (3) arranged to drive the screw (2) in rotation. The actuator also has a mechanism (92) for comparing the actual position of the nut relative to the frame (10) with a theoretical position for the nut relative to the frame (10) in order to obtain a position deviation (δang4, δlin4) of the nut; and a mechanism (93) for determining a force applied to the output (22.4) of the cable actuator (100) as a function of the position deviation of the nut. Also disclosed is a method of measuring a force applied to an output (16, 17, 24.1) of an actuator (100), and to a method of determining prior loading (t6,9) of a cable actuator (100).