The present invention is a computer method for determining the sheathing materials required for the construction of a building, comprising: receiving a model of a structure, wherein the model is comprised of a set of members; analyzing the set of members to determine a group of members associated with a roof line; processing the group of members to identify member specific properties; identifying, by one or more processors, a set of sheathing material to be applied to the group of members; converting the set of sheathing material to substantially cover the exterior surface of the model, wherein the a group of the sheathing material are modified; rendering, by one or more processors, an image of the placement of the set of sheathing material over the group of members; and calculating, by one or more processors, a set of data associated with each piece of the set of sheathing material.

The present invention is a computer method for determining the sheathing materials required for the construction of a building, comprising: receiving a model of a structure, wherein the model is comprised of a set of members; analyzing the set of members to determine a group of members associated with an exterior surface of the model; processing the group of members to identify member specific properties; identifying, by one or more processors, a set of sheathing material to be applied to the group of members; converting the set of sheathing material to substantially cover the exterior surface of the model, wherein the a group of the sheathing material are modified; rendering, by one or more processors, an image of the placement of the set of sheathing material over the group of members; and calculating, by one or more processors, a set of data associated with each piece of the set of sheathing material.

The present invention is a computer method for determining the sheathing materials required for the construction of a building, comprising: receiving a model of a structure, wherein the model is comprised of a set of members; analyzing the set of members to determine a group of members associated with an exterior surface of the model; processing the group of members to identify member specific properties; identifying, by at least one processor, a set of sheathing material to be applied to the group of members; converting the set of sheathing material to substantially cover the exterior surface of the model, wherein the a group of the sheathing material are modified; rendering, by at least one processor, an image of the placement of the set of sheathing material over the group of members; and calculating, by at least one processor, a set of data associated with each piece of the set of sheathing material.

The present invention is a computer-implemented method comprising: receiving at least one architectural drawing; analyzing each of the at least one architectural drawing, wherein non-structural elements are removed from each of the at least one architectural drawing; generating structural drawings for each of the at least one architectural drawing; marking each element within the structural drawings; generating a 3D model based on the structural drawings; analyzing the 3D model, wherein the 3D model is tested for predetermined characteristics; and generating a report based on the analyzed results of the predetermined characteristics.

The present invention is a computer method for determining the sheathing materials required for the construction of a building, comprising: receiving a model of a structure, wherein the model is comprised of a set of members; analyzing the set of members to determine a group of members associated with an exterior surface of the model; processing the group of members to identify member specific properties; identifying, by at least one processor, a set of sheathing material to be applied to the group of members; converting the set of sheathing material to substantially cover the exterior surface of the model, wherein the a group of the sheathing material are modified; rendering, by at least one processor, an image of the placement of the set of sheathing material over the group of members; and calculating, by at least one processor, a set of data associated with each piece of the set of sheathing material.

A monitoring and control system includes a stationary body with a sensor, a moving body with a sensor, and at least one computing device. The stationary body is positioned along a path of movement. The moving body moves along the path and physically interacts with the stationary body. The at least one computing device receives signals from the sensor on the stationary body and from the sensor on the moving body. The at least one computing device determines a performance value of the stationary or moving body based on the physical interaction between the moving and stationary bodies. The performance value is dependent on both of the signals received from the sensor associated with the stationary body and received from the sensor associated with the moving body as the moving body interacts with the stationary body.

According to embodiments, an ultrasonic inspection apparatus comprises: an ultrasonic array probe having a plurality of ultrasonic elements; an estimated shape reflected wave arrival time calculator for computing the estimated shape reflected wave arrival time for the estimated shape reflected wave on the basis of the estimated sound velocity in the test object; an actual shape reflected wave arrival time extractor for extracting the actual shape reflected wave arrival time on the basis of the actual shape reflected wave; a shape reflected waves time difference calculator for computing the difference by subtracting the actual shape reflected wave arrival time from the estimated shape reflected wave arrival time as shape reflected waves time difference; and a delay time calculator for computing the delay times for mutually shifting the timings of ultrasonic wave transmission and ultrasonic wave reception by the ultrasonic elements, considering the shape reflected waves time differences.

An adjustable filtration assembly performs water filtration tests from a sample point. A container contains a water solution. An inlet valve enables a flow of the water solution into the container. An adjustable pressure regulator valve regulates the flow. A relief valve releases a portion of the water solution when a pressure of the water solution exceeds a threshold pressure. A differential pressure gauge displays a current pressure reading of the water solution in the container, receives adjustments specifying a specific pressure to be maintained, maintains the specific pressure of the water solution, and triggers the relief valve when the pressure exceeds the specific pressure. An outlet valve, when opened, outputs a measured volume of the water solution. A filter membrane mounted in the outlet valve filters solids from the measured volume. A relative plugging index (RPI) of the water solution is determined based on a weight of the solids.

The present disclosure relates to a method for predicting a rubber reinforcing effect of an organic-inorganic composite for rubber reinforcement. According to the present disclosure, a method for reliably predicting a rubber reinforcing effect of an organic-inorganic composite for rubber reinforcement by thermogravimetric analysis without mixing with a rubber composition is provided.

The present disclosure relates to a method for predicting a rubber reinforcing effect of an organic-inorganic composite for rubber reinforcement. According to the present disclosure, a method for reliably predicting a rubber reinforcing effect of an organic-inorganic composite for rubber reinforcement by thermogravimetric analysis without mixing with a rubber composition is provided.