RU2011154213A - HYDRAULIC DISK PUMP - Google Patents

Abstract

1. A pump comprising a pump casing having a substantially cylindrical shape and forming a resonator for accommodating a fluid formed by a side wall closed at both ends by substantially circular end walls, with at least one of the end walls being driven by an end wall having a central section and a peripheral section extending radially outward from the central section of the driven end wall, a drive functionally connected to the central section of the driven end wall to create an oscillatory motion of the driven end wall, thus creating displacement oscillations of the driven end wall in the direction along substantially perpendicular thereto, with an annular assembly between the center of the driven end wall and the side wall, in use, an insulator functionally associated with the peripheral portion of the driven end wall to reduce displacement vibration damping, a first hole located at any location in the resonator other than m the location of the annular assembly, and passing through the pump housing, a second opening located at any location in the pump housing other than the location of the first opening, and passing through the pump housing, and a valve located in at least one of the first and second openings, the oscillations the displacements create corresponding radial fluctuations in fluid pressure within the resonator of the pump housing, creating fluid flow through said first and second openings in use. The pump according to claim 1, in which the ratio of the radius (r) of the resonator passing from the longitudinal axis of the resonator to the lateral �

Claims (52)

1. A pump comprising a pump housing having a substantially cylindrical shape and forming a resonator for accommodating a fluid, formed by a side wall closed at both ends by substantially circular end walls, wherein at least one of the end walls is driven an end wall having a central portion and a peripheral portion extending radially outward from the central portion of the driven end wall, an actuator operably coupled to the central portion of the driven end wall to generate a vibration the movement of the driven end wall, thereby creating fluctuations in the bias of the driven end wall in a direction substantially perpendicular to it, with an annular assembly between the center of the driven end wall and the side wall, when used, an insulator functionally connected to the peripheral portion of the driven end wall to reduce damping of displacement vibrations, the first hole located at any location in the cavity, except for the location of the annular assembly, and passing through the pump housing, the second hole e, located at any location in the pump housing other than the location of the first hole, and passing through the pump housing, and a valve located in at least one of the first and second holes, the bias oscillations creating corresponding radial fluctuations in the pressure of the fluid inside the resonator of the housing pump, creating a fluid flow through the aforementioned first and second openings when used. 2. The pump according to claim 1, in which the ratio of the radius (r) of the resonator extending from the longitudinal axis of the resonator to the side wall to the height (h) of the side wall of the resonator is more than about 1.2. 3. The pump according to claim 2, in which the height (h) of the resonator and the radius (r) of the resonator are additionally connected by the following ratio: h ² / r> 4 · 10 ^-10 m 4. The pump according to claim 2, in which the second hole is located in one of the end walls at a distance of approximately 0.63 (r) ± 0.2 (r) from the center of the end wall. 5. The pump according to claim 2, in which the drive is capable of driving the end wall connected to it to create oscillatory motion at a frequency (f). 6. The pump according to claim 2, in which the drive is capable of driving the end wall connected to it to create oscillatory motion at a frequency (f), while the radius (r) is related to the frequency (f) by the following relation:

where c _s = ≈115 m / s, c _f ≈1970 m / s, and k ₀ = 3.83. 7. The pump according to claim 1, in which the lowest resonant frequency of radial pressure fluctuations is more than approximately 500 Hz. 8. The pump according to claim 1, in which the oscillation frequency of the displacement of the driven end wall is approximately equal to the lowest resonant frequency of the radial pressure fluctuations. 9. The pump according to claim 1, in which the oscillation frequency of the displacement of the driven end wall is within 20% of the lowest resonant frequency of the radial pressure oscillations. 10. The pump according to claim 1, in which the oscillation displacement of the driven end wall has an oscillation shape consistent with radial pressure fluctuations. 11. The pump of claim 1, wherein said valve allows fluid to flow through the resonator in substantially the same direction. 12. The pump according to claim 1, in which the insulator is a flexible membrane. 13. The pump of claim 12, wherein the flexible membrane is formed of plastic. 14. The pump according to item 13, in which the annular width of the flexible membrane is approximately between 0.5 and 1.0 mm, and the thickness of the flexible membrane is less than approximately 200 microns. 15. The pump of claim 12, wherein the flexible membrane is formed of metal. 16. The pump according to clause 15, in which the annular width of the flexible membrane is approximately between 0.5 and 1.0 mm, and the thickness of the flexible membrane is less than approximately 20 microns. 17. The pump according to claim 1, in which the side wall of the pump contains a recess extending radially outward of the adjacent at least one of the end walls inside the resonator. 18. The pump according to claim 2, in which the ratio r / h is between about 10 and about 50, when in use the fluid inside the resonator is gas. 19. The pump according to claim 3, in which the ratio h ² / r is between about 10 ^-3 m and about 10 ^-6 m, when in use the gas inside the resonator is gas. 20. The pump according to claim 2, in which the volume of the resonator is less than approximately 10 ml 21. The pump according to claim 1, further comprising a second drive operably coupled to a central portion of the other end wall to vibrate said end wall in a direction substantially perpendicular thereto, and a second insulator operably coupled to a peripheral portion of said end wall for reduce damping of its vibrational motion by the side wall inside the resonator. 22. The pump according to claim 2, in which the radius of the drive is greater than or equal to 0.63 (r). 23. The pump according to item 22, in which the radius of the drive is less than or equal to the radius (r) of the resonator. 24. The pump according to claim 1, in which the drive contains a piezoelectric component to create oscillatory motion. 25. The pump according to claim 1, in which the drive contains a magnetostrictive component to create oscillatory motion. 26. A pump comprising a pump housing having a substantially cylindrical resonator having a side wall closed by two end surfaces to accommodate a fluid, the resonator having a height (h) and a radius (r) in which the radius ratio (r) to a height (h) of more than about 1.2, a drive functionally connected to the central portion of one end surface and adapted to create an oscillatory movement of the end surface, with an annular assembly between the center of the end surface and the side wall, at and In use, an insulator operably coupled to the peripheral portion of the end surface to reduce vibration damping, a first hole located at any location in the cavity other than the location of the ring assembly and passing through the pump body, a second hole located at any location in the pump body, the location of said first hole, and passing through the pump housing, and a valve located in at least one of the first and second holes to provide The passage of fluid through the resonator during use. 27. The pump according to p, in which the oscillatory movement creates radial fluctuations in the pressure of the fluid inside the resonator, creating a flow of fluid through the aforementioned first hole and second hole. 28. The pump according to item 27, in which the lowest resonant frequency of radial pressure fluctuations is more than approximately 500 Hz. 29. The pump according to item 27, in which the frequency of the oscillatory motion is approximately equal to the lowest resonant frequency of the radial pressure fluctuations. 30. The pump according to item 27, in which the frequency of the oscillatory motion is within 20% of the lowest resonant frequency of the radial pressure fluctuations. 31. The pump according to item 27, in which the oscillatory movement has an oscillation shape consistent with radial pressure fluctuations. 32. The pump according to p. 26, in which the side wall of the pump contains a recess extending radially outward near at least one of the end walls inside the resonator. 33. The pump according to p. 26, in which the height (h) of the resonator and the radius (r) of the resonator are additionally connected by the following ratio: h ² / r> 4 · 10 ^-10 m 34. The pump according to p. 26, in which the drive is capable of driving the end surface of the resonator connected to it, to create oscillatory motion at a frequency (f), while the radius (r) is connected with the frequency (f) by the following relation:

where c _s = ≈115 m / s, c _f ≈1970 m / s, and k ₀ = 3.83. 35. The pump according to p, in which the insulator is a flexible membrane. 36. The pump according to clause 35, in which the flexible membrane is formed of plastic. 37. The pump according to clause 36, in which the annular width of the flexible membrane is approximately between 0.5 and 1.0 mm, and the thickness of the flexible membrane is less than approximately 200 microns. 38. The pump according to clause 35, in which the flexible membrane is formed of metal. 39. The pump according to § 38, in which the annular width of the flexible membrane is approximately between 0.5 and 1.0 mm, and the thickness of the flexible membrane is less than approximately 20 microns. 40. The pump according to p, in which the radius of the drive is greater than or equal to 0.63 (r). 41. The pump of claim 40, wherein the radius of the drive is less than or equal to the radius (r) of the resonator. 42. The pump according to p. 26, in which the second hole is located in one of the end surfaces at a distance of approximately 0.63 (r) ± 0.2 (r) from the center of the end surface. 43. The pump according to p. 26, in which the valve allows the passage of fluid through the resonator in essentially one direction. 44. The pump of claim 26, wherein the r / h ratio is between about 10 and about 50, when in use, the gas inside the resonator is gas. 45. The pump of claim 26, wherein the h ² / r ratio is between about 10 ⁻³ m and about 10 ⁻⁶ m, when in use, the gas inside the resonator is gas. 46. The pump according to p, in which the volume of the resonator is less than approximately 10 ml 47. The pump of claim 26, further comprising a second drive operably coupled to a central portion of the other end surface of the resonator to create oscillatory motion of said end surface, and a second insulator operably coupled to a peripheral portion of said end surface to reduce vibration damping. 48. The pump according to p. 26, in which the drive contains a piezoelectric component in order to cause oscillatory motion. 49. The pump according to p. 26, in which the drive contains a magnetostrictive component to create oscillatory motion. 50. The pump according to p. 26, in which one of the end surfaces of the resonator has the shape of a truncated cone, while the height (h) of the resonator varies from a first height approximately in the center of one end surface to a second height near the side wall, smaller than the first height. 51. The pump according to p. 26, in which one of the end surfaces of the resonator has the shape of a truncated cone, while the height (h) of the resonator increases from the first height approximately at the center of one end surface to the second height near the side wall. 52. The pump of claim 51, wherein the ratio of the first height to the second height is at least about 50%.