1. Field
Embodiments of the disclosure relate generally to the field of synthetic actuators for fluidic effects and more particularly to a device having a cavity with a primary aperture and check valve, employing a piston to energize fluid within the cavity for flow through the check valve inducing a pressure reduction relative to the primary aperture creating a synthetic vacuum.
2. Background
Fluidic jets including synthetic jets are employed for control of flow on various aerodynamic surfaces. Boundary layer control for drag reduction to increase fuel efficiency and for aerodynamic controls on flight vehicles as well as turbulence reduction for such applications as improved aero-optical performance of electro-optical turrets.
It is also well known that boundary layer control may be accomplished by vacuum orifices on the controls or flight surfaces. Laminar flow separation can be delayed or eliminated with the use of properly placed vacuum “sinks”. The most prevalent existing solution for creation of vacuum at the orifices is to connect tubes to a centrally located vacuum pump. Vacuum pumps are often heavy and tubing is cumbersome. Highly complex vacuum pumping and routing systems from surface orifices have been employed in prior art systems to provide desired vacuum “point sinks” for boundary layer control. Investigations of improved efficiency fluidic and synthetic jets designed to impart energy into boundary layer airflow over aerodynamic surfaces revealed new and unexpected results. During test and evaluation of such new synthetic and fluidic jets for use in boundary layer control, it was unexpectedly discovered that under certain conditions, instead of an expected outward jet, a vacuum could be established.
It is therefore desirable to provide new structures and methods that can establish a vacuum source for boundary layer control which improves efficiency, lowers structural weight, and alleviates the complexity of current vacuum systems.
Embodiments disclosed herein provide a synthetic vacuum generator having a case enclosing an interior cavity with a primary aperture through the case in communication with the cavity. A piston and a check valve are mounted in the case in fluid communication with the cavity and the primary aperture. The piston and check valve are configured with symbiotic resonant response to establish an outflow there through and inducing an inflow through the primary aperture upon reciprocation of the piston at a predetermined frequency.
The embodiments disclosed provide a method for generation of a synthetic vacuum by inserting a piston into a cavity in a case having a primary aperture. An exhaust aperture in the case is resiliently sealed with a check valve. The piston is then reciprocated at a frequency to establish symbiotic resonant response between the piston and check valve thereby creating a synthetic vacuum at the primary aperture.
The features, functions, and advantages that have been discussed can be achieved independently in various embodiments of the present disclosure or may be combined in yet other embodiments further details of which can be seen with reference to the following description and drawings.
Embodiments disclosed herein provide a synthetic vacuum generator employing a case having an enclosed cavity with a piezo electrically activated piston operatively engaged in the case in fluid communication with the cavity. A check valve operatively engaged in the case in fluid communication with the cavity is resonantly activated by the piston to create a fluid inflow into the cavity through a primary aperture in the case.
Referring to the drawings,
In conventional low frequency reciprocation of the piston 16 in the configuration as shown, the check valve 20 would close when the piston 16 was reciprocated downward and result in a compression of the air in the cavity 14 as shown in
However, with higher frequency operation of the piston 16 with a piezo electric actuator, which will be described subsequently, at a predetermined frequency it has been demonstrated that a cooperative resonance between the piston and check valve may be established where the check valve moves inward into the cavity as the piston move inward into the cavity, defined herein as symbiotic motion or symbiotic resonant response of the check valve and piston. As shown in
As shown in
Motion of the air mass (represented schematically as element 60,
A transfer function that may be employed for modeling the behavior of the synthetic vacuum generator relative to properties of the piston 16, check valve 20 and primary aperture 26 for the desired symbiotic resonant response may be characterized for an exemplary embodiment by
where mh is the mass of the air in the primary aperture, mp is the mass of the piston and mv is the mass of the valve and kh, is the stiffness of air mass due to the cavity volume, kp is the stiffness of the suspension of the piston and kv is the stiffness of the springs (or resilience) urging sealing of the check valve.
The values kij are the coupling between each of the resonant systems which are the piston vibrating on its suspension and the valve vibrating on its support springs as in the block diagram embodiment of
The values for all of the m and k coefficients are functions of the area of the primary aperture sh the area of the piston, sp, and the opening area of the check valve, sv.
When the values are set to
kh=beta*sh2; (the product of the bulk modulus divided by cavity volume and the primary aperture area squared)
k12=beta*sp*sh; (the product of the bulk modulus divided by cavity volume, the piston area and the primary aperture area)
k13=beta*sv*sh; (the product of the bulk modulus divided by cavity volume, the check valve opening area and the primary aperture area)
k21=beta*sp*sh; (the product of the bulk modulus divided by cavity volume, the piston area and the primary aperture area)
kp=beta*sp2+kpstiff; (the product of the bulk modulus divided by cavity volume and the piston area squared added to the piston suspension stiffness)
k23=beta*sv*sp; (the product of the bulk modulus divided by cavity volume, the check valve area and the piston area)
k31=beta*sv*sh; (the product of the bulk modulus divided by cavity volume, the check valve opening area and the primary aperture area)
k32=beta*sv*sp; (the product of the bulk modulus divided by cavity volume, the check valve area and the piston area)
kv=beta*sv2+kvstiff; (the product of the bulk modulus divided by cavity volume and the check valve opening area squared added to the valve suspension stiffness)
where
beta is the bulk modulus divided by cavity volume
kpstiff=1/8.7e-5*4.4*39.4; the piston suspension stiffness with units of N/m
kvstiff=2000; the valve suspension stiffness with units of N/m
sp=pi*(1.22/39.4)2; the piston area with units of m2
sh=0.04/39.4*2/39.4; the primary aperture area with units of m2
sv=sh*0.05; the check valve opening area with units of m2
vol=0.06/39.4*sp; the cavity volume with units of m3
mp=pi*1.22̂2*0.125*0.1/2.2; mass of the piston in units of kg
ma=sh*0.02*1.2; mass of air in the cavity in units of kg
mv=mp/1000; mass of the check valve in units of kg
The resulting transfer function relating the motion of the check valve to the motion of the piston is shown in
As seen in
If the resonant frequency of the valve is tuned so that it is slightly above the ˜1300 Hz resonant frequency of the piston, which is illustrated in this
The symbiotic motion of the piston and check valve, the check valve moving into the cavity, providing flow through the exhaust port, as the piston is moving into the cavity and the check valve moving outward with respect to the cavity, sealing the cavity, while the piston is moving outward with respect to the cavity results in a reduced pressure in the cavity for inflow through the primary aperture as previously described with respect to
An amplification structure frame 30 for piezoelectric actuation of the piston 16 is attached to the case 12. Laterally spaced flexing end beams 32a and 32b support the frame 30 from attachment brackets 34a and 34b which are attached to the case 12. A first pair of opposing actuation beams 36a and 36b extend angularly from the end beams 32a and 32b, respectively, to suspend a center shaft 38. A second pair of actuation beams 40a and 40b, which are spaced longitudinally from the first actuation beam pair 36a, 36b, extend angularly from the end beams 32a and 32b to the center shaft 38.
Actuation beams 40a and 40b are parallel to actuation beams 36a and 36b, extending from the end beams 32a and 32b at the same relative extension angle. The actuation beams are interconnected to the end beams and center shaft with flexible joints 44. For the embodiment shown, the joints 44 are flexible webs machined or etched between the end beams and actuation beams and the center shaft and actuation beams. In alternative embodiments, pinned connections may be employed. The components of the amplification structure frame 30 may be fabricated from aluminum (an example embodiment employs 2024 aluminum), titanium, beryllium or beryllium alloys such as beryllium copper, steel or carbon fiber reinforced plastics.
A piezoceramic actuation assembly 46 provides the piezo electric actuator for the amplification structure frame 30 and extends between the end beams 32a and 32b centered intermediate the first pair of actuation beams 36a, 36b and second pair of actuation beams 40a, 40b. Activation of piezoelectric elements in the actuation assembly 46 provides a first condition with lateral extension or second condition with lateral contraction of the assembly which, in turn increases or decreases the lateral distance between the end beams.
An increase in the lateral distance of the end beams to a first relative lateral position (relative to the first condition) results in a reduction in angle to a first extension angle of the actuation beam pairs while a decrease in the lateral distance to a second relative lateral position (relative to the second condition) results in an increase in the angle to a second extension angle. The varying extension angle of the actuation beam pairs creates longitudinal motion of the center shaft 38 along axis 17 for reciprocation of the piston 16 with an amplification of the relative distance of the center shaft between a first longitudinal position at the first extension angle and a second longitudinal position at the second extension angle.
For the embodiment shown, the piezoceramic actuation assembly 46 operates orthogonally to the center shaft 38 on a non-interference basis. For the embodiment shown in
In alternative embodiments, a collar in the form of a U or semi-cylindrical element which partially surrounds the shaft may be employed. The collar may additionally provide a clearance for the shaft in the aperture, as for the embodiment shown, or closely receive the shaft to act as a guide element to limit shaft lateral deflection. The piezoceramic stacks 56a and 56b can be formed from low voltage piezoceramic having monolithic ceramic construction made from many thin piezoceramic layers electrically connected in parallel, or in any host of other equally effective arrangements available from many sources that offer piezoelectric/piezoceramic actuators and stacks.
In other alternative embodiments, the piezoceramic actuation assembly may employ a single piezoceramic stack which extends from the end beams through a slot in the center shaft. In any of the embodiments, the attachment brackets may be rigidly mounted to the case and the piezoceramic actuation assembly is maintained in a stationary position while the center shaft is translated longitudinally. This structure significantly reduces the moving mass allowing a higher translation frequency for the shaft 38 to be created by the amplification structure frame 30.
The embodiments provide a method for synthetic creation of a vacuum as shown in
Having now described various embodiments of the disclosure in detail as required by the patent statutes, those skilled in the art will recognize modifications and substitutions to the specific embodiments disclosed herein. Such modifications are within the scope and intent of the present disclosure as defined in the following claims.