A pair of insertion portions each having a through hole through which a lashing belt is inserted and extends are arranged at a predetermined distance from each other, and coupled to each other with coupling portions. A tension detecting portion is provided at the coupling portions. The tension detecting portion extends, at a predetermined vertical distance from a line connecting the through holes of the pair of insertion portions to each other, in a width direction of the lashing belt. In a state where the lashing belt is inserted to extend through the pair of insertion portions, a surface of the lashing belt is brought into contact with the tension detecting portion, and the tension detecting portion is configured to be broken when a predetermined or greater tension is applied to the lashing belt.

A pair of insertion portions each having a through hole through which a lashing belt is inserted and extends are arranged at a predetermined distance from each other, and coupled to each other with coupling portions. A tension detecting portion is provided at the coupling portions. The tension detecting portion extends, at a predetermined vertical distance from a line connecting the through holes of the pair of insertion portions to each other, in a width direction of the lashing belt. In a state where the lashing belt is inserted to extend through the pair of insertion portions, a surface of the lashing belt is brought into contact with the tension detecting portion, and the tension detecting portion is configured to be broken when a predetermined or greater tension is applied to the lashing belt.

The invention relates to a device for measuring the tension in a tensioning belt, comprising a retaining device for retaining a spring element, an elastically deformable spring element that is retained by the retaining device and on which a section of the tensioning belt can apply a force and elastically deform the spring element the ends of the spring element being moved closer to one another when the tensioning force increases, and an electronic sensor unit. The sensor unit comprises a sensor system that measures the deflection of the spring element and generates a data signal, and a transmitter for transmitting the data signal to a receiving unit. The sensor system is situated at the ends of the spring element. The sensor unit may also be used for documenting the measured values of the tension.

The invention relates to a device for measuring the tension in a tensioning belt, comprising a retaining device for retaining a spring element, an elastically deformable spring element that is retained by the retaining device and on which a section of the tensioning belt can apply a force and elastically deform the spring element the ends of the spring element being moved closer to one another when the tensioning force increases, and an electronic sensor unit. The sensor unit comprises a sensor system that measures the deflection of the spring element and generates a data signal, and a transmitter for transmitting the data signal to a receiving unit. The sensor system is situated at the ends of the spring element. The sensor unit may also be used for documenting the measured values of the tension.

The invention relates to a load detection unit having a spring-elastic load carrier assembly for receiving the load (10) and a sensor (3) for the deformation of the load carrier assembly, which occurs under the load (10) that is to be detected, wherein a deformation transmission unit (6) is operatively arranged between the load carrier assembly and the sensor (3). A method, in which additionally a deformation transmission unit is used, is thus provided, which during operation picks up the deformation of the load carrier assembly and transmits it to the sensor as a changed force/path load.

The invention relates to a load detection unit having a spring-elastic load carrier assembly for receiving the load (10) and a sensor (3) for the deformation of the load carrier assembly, which occurs under the load (10) that is to be detected, wherein a deformation transmission unit (6) is operatively arranged between the load carrier assembly and the sensor (3). A method, in which additionally a deformation transmission unit is used, is thus provided, which during operation picks up the deformation of the load carrier assembly and transmits it to the sensor as a changed force/path load.

A tension measuring apparatus includes a displacement part that is displaced in accordance with tension or a change of the tension of a wire rod to be measured when the displacement part is caused to abut against the wire rod to receive the tension of the wire rod, an elastic body that is elastically deformed in accordance with displacement of the displacement part, and a heat flow sensor that detects a heat flow caused by elastic deformation of the elastic body.

A tension measuring apparatus includes a displacement part that is displaced in accordance with tension or a change of the tension of a wire rod to be measured when the displacement part is caused to abut against the wire rod to receive the tension of the wire rod, an elastic body that is elastically deformed in accordance with displacement of the displacement part, and a heat flow sensor that detects a heat flow caused by elastic deformation of the elastic body.

The present invention relates to a system for monitoring tension forces of tendons in post-tensioning that accurately measures the tension forces of the tendons and/or controls the tension forces introduced into the tendons through a main server, thereby allowing the tension forces to be applied uniformly to the tendons.

According to the present invention, there is provided the system for monitoring tension forces of tendons disposed inside a concrete structure in post-tensioning, the system including: a hydraulic jack coupled to one tendon at one end of the concrete structure to apply the tension force to the tendon by means of the forward movement of a piston; a hydraulic pump connected to the hydraulic jack by means of a hydraulic pressure supply pipe to supply a hydraulic pressure to the hydraulic jack; a digital elongation length measurement sensor disposed on the hydraulic jack to measure the elongation length of the piston; a measurement unit having a data logger adapted to receive and store the elongation length data measured by the digital elongation length measurement sensor and to send the elongation length data to a main server; a digital pressure measurement sensor disposed on the hydraulic pressure supply pipe of the hydraulic pump; and a control module adapted to receive the elongation length data from the data logger or the main server, calculate the tension force, compensate for the coefficient of elasticity of the tendon according to the ratio of the real-time elongation length data to the pressure data, and compensate for the tension force calculated.

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.