The disclosure generally relates to vortices and more particularly relates to systems and methods for actively controlling a vortex in a fluid.
Wall-bounded vortex arises in both nature and various engineering applications. There have been efforts to understand the dynamics of vortices and to develop techniques to modify their behavior. Flow control is often employed to diminish the appearance of vortices or alter the characteristics of vortices in a liquid. For example, in a sump pump, the emergence of submerged vortices may degrade pump performance. If the submerged vortices are sufficiently strong, these vortices can include strong low-pressure cores, which can entrain air/vapor along their vortex cores. If such hollow-core vortices are engulfed by the pump, they can cause unbalanced loading and vibration, leading to undesirable noise and possible structural failure. Strong wall-normal vortices appear inside and outside of many fluid-based machines as well as in natural settings, including tornadoes and hurricanes.
There have been numerous attempts to introduce passive vortex control techniques to prevent the generation of the aforementioned vortices or alter their pressure distributions. Yet passive control techniques do not offer the ability to adaptively adjust the control efforts to unsteady flow conditions (beyond design conditions). Moreover, some passive control devices are difficult to manufacture. Thus, these past efforts have shortcomings in offering reliable techniques to modify the pressure distribution of these vortices. Designing a more efficient and flexible vortex control strategy remains a challenge.
In certain embodiments, a vortex control device for modifying a vortex in a fluid stemming from a wall is disclosed. The device includes a rotatable hub disposed within an opening in the wall. The device also includes an inlet port and an outlet port in the rotatable hub. The inlet port forms a suction port to suction fluid from or about the vortex, and the outlet port forms an injection port to inject fluid into or about the vortex. The device may therefore alter a pressure distribution of the vortex by injecting momentum perturbations to the flow.
The detailed description is set forth with reference to the accompanying drawings. The use of the same reference numerals may indicate similar or identical items. Various embodiments may utilize elements and/or components other than those illustrated in the drawings, and some elements and/or components may not be present in various embodiments. Elements and/or components in the figures are not necessarily drawn to scale. Throughout this disclosure, depending on the context, singular and plural terminology may be used interchangeably.
The present disclosure is directed to spreading the core region of a coherent wall-normal vortex and alleviating the low-pressure in the core in a flow field. Such vortices are ubiquitous in nature and engineering systems, ranging from hydrodynamic/aerospace applications to nature, such as hurricanes and subsurface vortices. Many passive control techniques exist for wall-normal vortices, but none include active flow control methods that can be applied in an adaptive manner. To solve this problem, the present disclosure introduces a control device comprising forcing input (e.g., a fluid jet and suction) at or near the core region of the vortex to destabilize the local flow and spread the core region. The injected fluid modifies the dynamics of the vertical flow and lowers the local angular velocity, increasing the core pressure of the vortex. The increase of the pressure has engineering benefits because low pressure at the core can create detrimental engineering effects for vortices in air and liquids. In some instances, the forced input follows a sinusoidal form in time and in a co-rotating/counter-rotating direction for effective breakup of the vortex.
The present disclosure provides a more adaptive technique than passive controls for alleviating the low-pressure effect of the vortex core using active flow control techniques. That is, the present disclosure provides a vortex control technique and device for control of vortices stemming from the wall in different flow conditions. To achieve this, two different types of control strategies are disclosed based on co-rotating and counter-rotating mass injection and suction from the wall surface on which the vortex resides. The control strategy is employed on the wall where the vortex core is positioned and the mass injection/suction device is placed underneath the surface. The control device may be centered or off-centered from the core of the vortex. The control input is adjusted with its frequency, amplitude, and direction of mass injection/suction. The control device may draw fluid from the system that the vortex is formed and inject said fluid back into the system. That is, the same fluid in which the vortex is formed may be injected/suctioned at or about the vortex. In other instances, the control device may inject fluid from outside the system into the vortex. In some instances, injection/suction is introduced from multiple locations in a rotational manner with respect to the vortex core. These devices allow the control input to be tuned for vortices with different strengths.
Vortex Control Device
In certain embodiments, the vortex control device 100 includes a hub 106. The hub 106 may be disposed within an opening 108 in the wall plate 102. In some instances, the hub 106 includes a surface 110 that is flush with a surface 112 of the wall plate 102. In other instances, the surface 110 of the hub 106 may not be flush with the wall plate 102. That is, the surface 110 of the hub 106 may be recessed within the wall plate 102, or the surface 110 of the hub 106 may protrude out from the wall plate 102. The hub 106 may be any suitable size, shape, or configuration. The hub 106 may act as a stationary or rotating manifold for the vortex control device 100.
In certain embodiments, as depicted in
The angle of the port 109 may be controlled (e.g., tilted or the like) to further modify the vortex 104. For example, the blow or suction angle of the port 109 may be adjusted relative to the surface 110 of the hub 106. In other instances, the hub 106 itself may be manipulated (e.g., tilted) so as to adjust the blow and/or suction angles.
In one embodiment, the vortex control device 100 includes a pump 120 in fluid communication with the hub 106. In some instances, the pump may be in fluid communication with two conduits. For example, a first conduit 122 can be fluidly coupled to the port 109 such that the port 109 functions as a suction port. In other instances, the port 109 can be fluidly coupled to a second conduit 124 such that the port 109 functions as an injection port. The vortex control device 100 also may include a valve 126 to control the mass flow of the vortex control device 100. In this particular embodiment, the valve 126 is a rotary valve. However, any suitable valve 126 may be used. In other instances, the mass flow may be controlled via an inverter to control the pump speed.
As used herein, the term “fluidly couples” refers to the coupled parts being operably connected together and effective for a fluid to be communicated therebetween.
In other instances, as depicted in
In some instances, the hub 106 includes an inlet port 116 and an outlet port 118. The inlet port 116 may form a suction port, and the outlet port 118 may form an injection port. In some instances, the inlet port 116 and the outlet port 118 are located at or near a core of the vortex 104. In other instances, the inlet port 116 and the outlet port 118 are disposed around a perimeter of the vortex 104. The inlet port 116 and the outlet port 118 may be located in any suitable location about the vortex 104. In some instances, the vortex control device 100 may include a plurality of the number of inlet ports 116 and outlet ports 118. When a plurality of inlet ports 116 and outlet ports 118 are present, the inlet ports 116 and outlet ports 118 may be operated simultaneously. In other instances, the inlet ports 116 and outlet ports 118 may be selectively operated, such as in a predetermined sequence, e.g., serially. That is, some the inlet ports 116 and outlet ports 118 may be turned “on” while other are turned “off” at various times.
In any case, fluid, e.g., a liquid, may be drawn into the inlet port 116 and expelled out of the outlet port 118. As the hub 106 rotates within the wall plate 102, the location of the inlet port 116 and the outlet port 118 may rotate about the central axis 114. In some instances, the core of the vortex may be aligned with the central axis 114. In other instances, the core of the vortex may be offset from the central axis 114. To modify the vortex 104, the outlet port 118 is used to inject fluid, e.g., a liquid, into or about the vortex 104, and the inlet port 116 is used to suction fluid from or about the vortex 104. The inlet port 116 and the outlet port 118 may be operated simultaneously. That is, the inlet port 116 may suction fluid from or about the vortex 104 at the same time that the outlet port 118 injects fluid into or about the vortex 104. In other instances, the inlet port 116 and the outlet port 118 may not operate simultaneously. That is, only one of the inlet port 116 and the outlet port 118 may operate at once.
In certain embodiments, the angle of the inlet port 116 and the outlet port 118 may be controlled (e.g., tilted or the like) to further modify the vortex 104. For example, the blow angle of the outlet port 118 may be adjusted relative to the surface 110 of the hub 106. Similarly, the suction angle of the inlet port 116 may be adjusted relative to the surface 110 of the hub 106. In other instances, the hub 106 itself may be manipulated (e.g., tilted) so as to adjust the blow and/or suction angles.
In one embodiment, the vortex control device 100 includes a pump 120 in fluid communication with the hub 106. For example, a first conduit 122 fluidly couples the inlet port 116 to the pump 120, and a second conduit 124 fluidly couples the outlet port 118 to the pump 120. The vortex control devices 100 also may include a valve 126 to control the mass flow of the vortex control device 100. In this particular embodiment, the valve 126 is a rotary valve. However, any suitable valve 126 may be used. In other instances, the mass flow may be controlled via an inverter to control the pump speed.
As depicted in
The controller 128 may be in communication with at least one hub actuator 130, which may be in electrical and/or mechanical communication with the hub 106. In this manner, the hub actuator 130 may be configured to control the movement of the hub 106. For example, the hub actuator 130 may control the rotation or tilt of the hub 106 or the ports associated therewith. The controller 128 also may be in communication with at least one valve actuator 132, which may be in electrical and/or mechanical communication with the valve 126. In this manner, the valve actuator 132 may be configured to control the operation of the valve 126. In addition, the controller 128 may be in communication with the pump 120. In this manner, the controller 128 may be configured to control the operation of the pump 120.
Vortex Model
Extensive numerical simulation and experimental investigations were performed on a vortex control device. For example,
where vortex core size a0=1, circulation: Γ=9.848, uθ, max=1, and Re=Γ/ν=5000.
In one example, a submerged vortex model was a modification of Burgers vortex by a no-slip boundary condition along the symmetry plane. As depicted in
Inlet: (ur, uθ, uz); Outlet:
and Bottom: u=0. The control input comprised unsteady mass injection imposed from the lower surface, where us=A cos(θ+ωct)e−r
Mass Injection
The vortex control devices disclosed herein provide effective unsteady forcing for single-phase vortex modification. Co-rotating and counter-rotating forcing can excite vortex wake and instability, respectively. In the co-rotating vortex control case, as depicted in
As depicted in
Off-Centered Vortex Control
The robustness of the vortex control was evaluated using an off-centered approach. That is, the vortex control device was disposed off-center from the core of the vortex. As depicted in
The arrow in
The disclosed device/technique enables the modification of the vortex and alleviates the low-pressure core by introducing active mass injection/suction at ports on the surface in a circulation arrangement around the vortex core (e.g., centered and off-center). The blowing direction can be tuned but in general is oriented in a normal manner to the surface. Suction is also introduced with injection at different ports but at the same time. The strengths of injection and suction changes in time along the ports along their circular arrangement. The device can introduce mass injection and suction in a co-rotating or counter-rotating manner with respect to the wall-normal vortex.
Although specific embodiments of the disclosure have been described, numerous other modifications and alternative embodiments are within the scope of the disclosure. For example, any of the functionality described with respect to a particular device or component may be performed by another device or component. Further, while specific device characteristics have been described, embodiments of the disclosure may relate to numerous other device characteristics. Further, although embodiments have been described in language specific to structural features and/or methodological acts, it is to be understood that the disclosure is not necessarily limited to the specific features or acts described. Rather, the specific features and acts are disclosed as illustrative forms of implementing the embodiments. Conditional language, such as, among others, “can,” “could,” “might,” or “may,” unless specifically stated otherwise, or otherwise understood within the context as used, is generally intended to convey that certain embodiments could include, while other embodiments may not include, certain features, elements, and/or steps. Thus, such conditional language is not generally intended to imply that features, elements, and/or steps are in any way required for one or more embodiments.
The disclosure claims priority to and the benefit of U.S. provisional patent application No. 62/583,538, filed Nov. 9, 2017, which is incorporated by reference herein in its entirety.
Number | Date | Country | |
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62583538 | Nov 2017 | US |