A controlled turbulence system is disclosed to have a surface and means configured to induce a first wave form in a working fluid along the surface. Some embodiments of the invention may include a second means configured to induce a second wave form in the working fluid, wherein the first wave form and the second wave form have different frequencies. The first and/or second means may be provided as fields of pockets formed in the surface or wave-based generators.

A structural object includes a substrate integrally clad with a metallic glass sheet by adhering, welding or joining the metallic glass sheet on the substrate for a low-cost, flexible and convenient fabrication, assembly, processing or construction of the object.

An example implementation of the subject matter described within this disclosure is a thermowell with the following features. A body has a closed end, an open end, an outer surface, and defining an interior cavity starting prior to the closed end and terminating at the open end. The outer surface defines dimples that reduce vibration in response to vortex shedding.

A magnetic insertion meter is disclosed herein. Disclosed insertion meters include in some examples, a sensor head tube having a textured front surface and at least two electrodes. Disclosed insertion meters include a textured front surface adapted to move the separation point of a fluid flowing over the sensor head tube towards the upstream surface as compared to the same sensor head tube without the textured front surface. Methods of measuring flow are also disclosed herein using example magnetic insertion meters.

The approach to the current problem of plastic deformation on the walls of the transportation truck is the development of a tribodynamic cell. This geometrically manufactured shape is able to reduce the force of more than 60.00% in a truck, more than 80.00% as a unit cell at standard speeds, and 90.00% at sonic range velocities. This reduction signifies an economic savings in fuel, service life of the transportation system, as well as reducing the carbon footprint locally and worldwide. Strategically, the tribodynamic cell embodiments convert the immediate surrounding airflow into a surface capable of lowering friction drastically and achieving supersonic speeds in half the time compared to a surface without the geometrically enhanced approach.

A strut for a gas turbine engine includes an airfoil section extending in a spanwise direction between a first platform and a second platform, extending in a chordwise direction between a leading edge and trailing edge to define a chord length, and extending in a thickness direction between a first side and a second side to define a chord width. Exterior surfaces of the airfoil section define a leading portion between the leading edge and a widest location of the airfoil section relative to the thickness direction, and a trailing portion between the widest location and the trailing edge. The exterior surfaces establish a respective exterior contour for each span position between a 0% span position and a 100% span position. The exterior surfaces define a plurality of dimples in the leading portion.

Body provided with a superficial area adapted to reduce drag when the body is moving relative to a gaseous or watery medium, comprising depressions in said superficial area, wherein the depressions have a greater length than width and are provided in the superficial area so as to collectively shape a curvature provided in a length direction of said depressions in the superficial area, and/or said depressions themselves are provided with a curvature in their length direction. The depressions are thus adapted to provide that a turbulent boundary layer of the gaseous or watery medium adjacent to the superficial area of the body is exposed to lateral excitation with reference to a movement direction of the body in the gaseous or watery medium or with reference to a flow direction of said turbulent boundary layer along said superficial area of the body. Said lateral excitation results in a reduction of drag.

Pressure oscillations or acoustic loads over an open type cavity having a front face an upper edge of which constitutes a leading edge and having a rear face an upper edge of which constitutes a trailing edge are reduced by applying curvature to the rear face so as to present a convex curved surface internal to the cavity. In one embodiment, a cross-section through a longitudinal axis of the convex curved surface describes part of an ellipse.

A drag reduction structure wherein a first portion including a plurality of convex portions and concave portions, and a second portion are placed on a first surface; a height from a bottom portion of the concave portion to a top portion of the convex portion, of the first portion, is 10 ?m or more and 1000 ?m or less; a length of the first portion in a second direction is 30 mm or more; and a width of the first portion and a width of the second portion, in a first direction crossing the second direction, is 0.2 mm or more and 50 mm or less.

Provided are an object surface structure for reducing fluid resistance and rectifying fluid, and a preparation method. The surface structure includes a basic surface of an object, arc protrusions formed by a plurality of cambered surface-shaped protrusions are distributed on the basic surface in an array; a rotatable object with an cambered surface in the pit on the basic surface is exposed to the cambered surface outside the pit to form a rotatable arc protrusion; or an cambered surface-shaped object fixed on the basic surface or an arc-shaped protrusion integrated with the basic surface forms a fixed arc protrusion; and the object surface structure provided with the plurality of arc protrusions forms an arc protrusion surface structure. With the application, the purposes of improving moving efficiency, reducing energy consumption of advancing apparatuses, improving advancing efficiency, reducing noise, reducing resonance and improving controllability of a moving object are achieved.