Claims
- 1. A multi-cylinder compressor, comprising:
a valve plate comprising a plurality of cylinder suction ports formed therethrough; a plurality of cylinder bores centered on an arc having a radius (R), wherein the cylinder bores are substantially equally spaced from each other, and have a diameter (D); and a suction chamber having a substantially annular shape and adapted to be in fluid communication with each of the cylinder bores via the suction ports, wherein a center of a first suction port is radially offset in a predetermined direction from a center of a predetermined suction port by a first angle, wherein the predetermined suction port has a diameter (d), and the first angle equals {[(360°/N)·([N−1]−n)]+X°}, in which N is a number of the suction ports formed through the valve plate, n is a number of the suction ports positioned between the first suction port and the predetermined suction port in a direction opposite to the predetermined direction, and X° is a predetermined angle which is less than or equal to {(sin−1[(D−d)/(2·R)]) ·57.3°/Radian} and greater than or equal to −{(sin−1[(D−d)/(2·R)])·57.3°/Radian}, and which is not equal to 0°.
- 2. The compressor of claim 1, further comprising a discharge chamber, wherein the valve plate further comprises a plurality of cylinder discharge ports formed therethrough, and the discharge chamber is adapted to be in fluid communication with each of the cylinder bores via the discharge ports, wherein the suction chamber extends around the discharge chamber.
- 3. The compressor of claim 1, wherein the predetermined direction is clockwise.
- 4. The compressor of claim 3, wherein the predetermined angle X° is a positive angle.
- 5. The compressor of claim 3, wherein the predetermined angle X° is a negative angle.
- 6. The compressor of claim 1, wherein the predetermined direction is counterclockwise.
- 7. The compressor of claim 6, wherein the predetermined angle X° is a positive angle.
- 8. The compressor of claim 6, wherein the predetermined angle X° is a negative angle.
- 9. The compressor of claim 1, wherein the predetermined direction is clockwise, and the predetermined suction port is positioned adjacent to the first suction port, wherein the predetermined angle X° is a negative angle.
- 10. The compressor claim 1, wherein a second of the suction ports is positioned adjacent to the first suction port, and a third of the suction ports is positioned adjacent to the second suction port, wherein the predetermined direction is clockwise, the predetermined suction port is the third suction port, and the predetermined angle X° is a positive angle.
- 11. The compressor claim 1, wherein a second of the suction ports is positioned adjacent to the first suction port, a third of the suction ports is positioned adjacent to the second suction port, and a fourth of the suction ports is positioned adjacent to the third suction port, wherein the predetermined direction is clockwise, the predetermined suction port is the fourth suction port, and the predetermined angle X° is a positive angle.
- 12. The compressor claim 1, wherein a second of the suction ports is positioned adjacent to the first suction port, a third of the suction ports is positioned adjacent to the second suction port, a fourth of the suction ports is positioned adjacent to the third suction port, and a fifth of the suction ports is positioned adjacent to fourth suction port, wherein the predetermined direction is clockwise, the predetermined suction port is the fifth suction port, and the predetermined angle X° is a negative angle.
- 13. The compressor claim 1, wherein a second of the suction ports is positioned adjacent to the first suction port, a third of the suction ports is positioned adjacent to the second suction port, a fourth of the suction ports is positioned adjacent to the third suction port, a fifth of the suction ports is positioned adjacent to fourth suction port, and a sixth of the suction ports is positioned adjacent to the fifth suction port, wherein the predetermined direction is clockwise, the predetermined suction port is the sixth suction port, and the predetermined angle X° is a negative angle.
- 14. The compressor of any of claims 5, 8, 9, 12, and 13, wherein the predetermined angle X° is about −10°.
- 15. The compressor claim 1, wherein a second of the suction ports is positioned adjacent to the first suction port, a third of the suction ports is positioned adjacent to the second suction port, a fourth of the suction ports is positioned adjacent to the third suction port, a fifth of the suction ports is positioned adjacent to fourth suction port, a sixth of the suction ports is positioned adjacent to the fifth suction port, and a seventh of the suction ports is positioned adjacent to the sixth suction port, wherein the predetermined direction is clockwise, the predetermined suction port is the seventh suction port, and the predetermined angle X° is a positive angle.
- 16. The compressor of any of claims 4, 7, 10, 11, and 15, wherein the predetermined angle X° is about 10°.
- 17. The compressor of claim 1, wherein the first suction port is radially offset from a first predetermined suction port by the first angle, and the first suction port is radially offset from a second predetermined suction port by a second angle, wherein the first predetermined suction port has a first diameter (d1), and the second predetermined suction port has a second diameter (d2), wherein the first angle equals {[(360°/N)·([N−1]−n)]+X1°} and the second angle equals {[(360°/N)·([N−1]−n)]+X2°}, in which X1° is a first predetermined angle which is less than or equal to {(sin−1[(D−d1)/(2·R)])·57.3°/Radian} and greater than or equal to −{(sin−1[(D−d1)/(2·R)])·57.3°/Radian}, and which is not equal to 0°, and X2° is a second predetermined angle which is less than or equal to {(sin−1[(D−d2 )/(2·R)])·57.320 /Radian} and greater than or equal to −{(sin−1[(D−d2)/(2·R)])·57.3°/Radian}, and which is not equal to 0°.
- 18. The compressor of claim 17, wherein a second of the suction ports is positioned adjacent to the first suction port, and a third of the suction ports is positioned adjacent to the second suction port, wherein the predetermined direction is clockwise, the first predetermined suction port is the second suction port, the second predetermined suction port is the third suction port, the first predetermined angle X1° is a negative angle, and the second predetermined angle X2° is a negative angle.
- 19. The compressor claim 18, wherein a second of the suction ports is positioned adjacent to the first suction port, a third of the suction ports is positioned adjacent to the second suction port, and a fourth of the suction ports is positioned adjacent to the third suction port, wherein the predetermined direction is clockwise, the first predetermined suction port is the third suction port, the second predetermined suction port is the fourth suction port, the first predetermined angle X1° is a positive angle, and the second predetermined angle X2° is a positive angle.
- 20. The compressor claim 18, wherein a second of the suction ports is positioned adjacent to the first suction port, a third of the suction ports is positioned adjacent to the second suction port, a fourth of the suction ports is positioned adjacent to the third suction port, a fifth of the suction ports is positioned adjacent to fourth suction port, and a sixth of the suction ports is positioned adjacent to the fifth suction port, wherein the predetermined direction is clockwise, the first predetermined suction port is the fifth suction port, the second predetermined suction port is the sixth suction port, the first predetermined angle X1° is a negative angle, and the second predetermined angle X2° is a negative angle.
- 21. The compressor of any of claims 18 and 20, wherein the first predetermined angle X1° is about −10° and the second predetermined angle X2° is about −10°.
- 22. The compressor claim 18, wherein a second of the suction ports is positioned adjacent to the first suction port, a third of the suction ports is positioned adjacent to the second suction port, a fourth of the suction ports is positioned adjacent to the third suction port, a fifth of the suction ports is positioned adjacent to fourth suction port, a sixth of the suction ports is positioned adjacent to the fifth suction port, and a seventh of the suction ports is positioned adjacent to the sixth suction port, wherein the predetermined direction is clockwise, the first predetermined suction port is the sixth suction port, the second predetermined suction port is the seventh suction port, the first predetermined angle X1° is a positive angle, and the second predetermined angle X2° is a positive angle.
- 23. The compressor of any of claims 19 and 22, wherein the first predetermined angle X1° is about 10° and the second predetermined angle X2° is about 10°.
- 24. The compressor claim 18, wherein a second of the suction ports is positioned adjacent to the first suction port, a third of the suction ports is positioned adjacent to the second suction port, a fourth of the suction ports is positioned adjacent to the third suction port, a fifth of the suction ports is positioned adjacent to fourth suction port, a sixth of the suction ports is positioned adjacent to the fifth suction port, and a seventh of the suction ports is positioned adjacent to the sixth suction port, wherein the predetermined direction is clockwise, the first predetermined suction port is the second suction port, the second predetermined suction port is the seventh suction port, the first predetermined angle X1° is a negative angle, and the second predetermined angle X2° is a positive angle.
- 25. The compressor of claim 24, wherein the first predetermined angle X1° is about −10° and the second predetermined angle X2° is about 10°.
- 26. The compressor of claim 18, wherein the first suction port is radially offset from a third predetermined suction port by a third angle, and the first suction port is radially offset from a fourth predetermined suction port by a fourth angle, wherein the third predetermined suction port has a third diameter (d3), and the fourth predetermined suction port has a fourth diameter (d4), wherein the third angle equals {[(360°/N)·([N−1]−n)]+X3°} and the fourth angle equals {[(360°/N)·([N−1]−n)]+X4°}, in which X3° is a third predetermined angle which is less than or equal to {(sin−1[(D−d3)/(2·R)])·57.3°/Radian} and greater than or equal to −{(sin−1[(D−d3)/(2·R)])·57.3°/Radian}, and which is not equal to 0°, and X4° is a fourth predetermined angle which is less than or equal to {(sin−1[(D−d4)/(2·R)])·57.3°/Radian} and greater than or equal to −{(sin−1[(D−d4)/(2·R)])·57.3°/Radian}, and which is not equal to 0°.
- 27. The compressor of claim 26, wherein a second of the suction ports is positioned adjacent to the first suction port, a third of the suction ports is positioned adjacent to the second suction port, a fourth of the suction ports is positioned adjacent to the third suction port, a fifth of the suction ports is positioned adjacent to fourth suction port, a sixth of the suction ports is positioned adjacent to the fifth suction port, and a seventh of the suction ports is positioned adjacent to the sixth suction port, wherein the predetermined direction is clockwise, the first predetermined suction port is the second suction port, the second predetermined suction port is the fourth suction port, the third predetermined suction port is the fifth suction port, and the fourth predetermined suction port is the seventh suction port, wherein the first predetermined angle X1° is a negative angle, the second predetermined angle X2° is a positive angle, the third predetermined angle X3° is a negative angle, and the fourth predetermined angle X4° is a positive angle.
- 28. The compressor of claim 27, wherein the first predetermined angle X1° is about −10°, the second predetermined angle X2° is about 10°, the third predetermined angle X3° is about −10°, and the fourth predetermined angle X4° is about 10°.
- 29. The compressor of claim 27, wherein the first suction port is radially offset from a fifth predetermined suction port by a fifth angle, and the first suction port is radially offset from a sixth predetermined suction port by a sixth angle, wherein the fifth predetermined suction port has a fifth diameter (d5), and the sixth predetermined suction port has a sixth diameter (d6), wherein the fifth angle equals {[(360°/N)·([N−1]−n)]+X5°} and the sixth angle equals {[(360°/N)·([N−1]−n)]+X6°}, in which X5° is a fifth predetermined angle which is less than or equal to {(sin−1[(D−d5)/(2·R)])·57.3°/Radian} and greater than or equal to −{(sin−1[(D−d5)/(2·R)])·57.3°/Radian}, and which is not equal to 0°, and X6° is a second predetermined angle which is less than or equal to {(sin−1[(D−d2)/(2·R)])·57.3°/Radian} and greater than or equal to −{(sin−1[(D−d2)/(2·R)])·57.3°/Radian, and which is not equal to 0°.
- 30. The compressor of claim 29, wherein the fifth predetermined suction port is the third suction port, the sixth predetermined suction port is the sixth suction port, the fifth predetermined angle X5° is a positive angle, and the sixth predetermined angle X6° is a negative angle.
- 31. The compressor of claim 30, wherein the first predetermined angle X1° is about −10°, the second predetermined angle X2° is about 10°, the third predetermined angle X3° is about −10°, the fourth predetermined angle X4° is about 10°, the fifth predetermined angle X5° is about 10°, and the sixth predetermined angle X6° is about −10°.
- 32. The compressor of claim 1, wherein at least one of the suction ports has a diameter between about 6 mm and about 14 mm.
- 33. The compressor of claim 32, wherein the suction chamber has a varying radius, and a mean radius of the suction chamber is between about 46 mm and about 54 mm.
- 34. A suction manifold joining a plurality of cylinders in a suction chamber, comprising:
a plurality of cylinder bores centered on an arc having a radius (R), wherein the cylinder bores are substantially equally spaced from each other, and have a diameter (D); and a valve plate comprising a plurality of cylinder suction ports formed therethrough, wherein a center of a first of the suction ports is radially offset in a predetermined direction from a center of a predetermined suction port by a first angle, wherein the predetermined suction port has a diameter (d), and the first angle equals {[(360°/N)·([N−1]−n)]+X°}, in which N is a number of the suction ports formed through the valve plate, n is a number of the suction ports positioned between the first suction port and the predetermined suction port in a direction opposite to the predetermined direction, and X° is a predetermined angle which less than or equal to {(sin−1[(D−d)/(2·R)])·57.3°/Radian} and greater than or equal to −{(sin−1[(D−d)/(2·R)])·57.3°/Radian}, and which is not equal to 0°.
- 35. The manifold of claim 34, wherein the predetermined direction is clockwise.
- 36. The manifold of claim 34, wherein the predetermined direction is counterclockwise.
- 37. The manifold of any of claims 35 and 36, wherein the predetermined angle X° is a positive angle.
- 39. The manifold of claim 37, wherein the predetermined angle X° is about 10°.
- 38. The manifold of any of claims 35 and 36, wherein the predetermined angle X° is a negative angle.
- 40. The manifold of claim 38, wherein the predetermined angle X° is about −10°.
- 41. The manifold of claim 34, wherein at least one of the suction ports has a diameter greater than about 6 mm and less than about 14 mm.
- 42. The manifold of claim 41, wherein at least one of the suction ports has a diameter of about 14 mm.
- 43. The manifold of claim 41, wherein the suction chamber has a varying radius, and a mean radius of the suction chamber is greater than about 46 mm and less than about 54 mm.
- 44. The manifold of claim 43, wherein the mean radius of the suction chamber is about 48 mm.
- 45. A multi-cylinder compressor, comprising:
a valve plate comprising a plurality of cylinder suction ports formed therethrough, wherein a first of the suction ports is positioned adjacent to a second of the suction ports, and the second suction port is positioned adjacent to a third of the suction ports; a plurality of cylinder bores; and a suction chamber having a substantially annular shape and adapted to be in fluid communication with each of the cylinder bores via the suction ports, wherein the second suction port is radially offset from the first suction port by a first angle, and the third suction port is radially offset from the second suction port by a second angle, wherein the first angle is greater than or less than the second angle.
- 46. The compressor of claim 45, further comprising a discharge chamber, wherein the valve plate further comprises a plurality of cylinder discharge ports formed therethrough, and the discharge chamber is adapted to be in fluid communication with each of the cylinder bores via the discharge ports, wherein the suction chamber extends around the discharge chamber.
- 47. The compressor of claim 45, wherein the second angle is greater than the first angle.
- 48. The compressor of claim 47, wherein the second angle is between about 10° and about 30° greater than the first angle.
- 49. The compressor of claim 48, wherein the second angle is about 30° greater than the first angle.
- 50. The compressor of claim 48, wherein the second angle is about 20° greater than the first angle.
- 51. The compressor of claim 45, wherein the first angle is greater than the second angle.
- 52. The compressor of claim 51, wherein the first angle is between about 10° and about 30° greater than the second angle.
- 53. The compressor of claim 52, wherein the first angle is about 30° greater than the second angle.
- 54. The compressor of claim 52, wherein the first angle is about 20° greater than the second angle.
- 55. The compressor of claim 45, wherein at least one of the suction ports has a diameter greater than about 6 mm and less than about 14 mm.
- 56. The compressor of claim 55, wherein the suction chamber has a varying radius, and a mean radius of the suction chamber is greater than about 46 mm and less than about 54 mm.
- 57. A valve plate assembly, comprising:
a valve plate comprising a plurality of cylinder suction ports formed therethrough, wherein a first of the suction ports is positioned adjacent to a second of the suction ports, and the second suction port is positioned adjacent to a third of the suction ports, wherein the second suction port is radially offset from the first suction port by a first angle, and the third suction port is radially offset from the second suction port by a second angle, wherein the first angle is greater than or less than the second angle.
- 58. The valve plate assembly of claim 57, wherein the second angle is greater than the first angle.
- 59. The valve plate assembly of claim 58, wherein the second angle is between about 10° and about 30° greater than the first angle.
- 60. The valve plate assembly of claim 59, wherein the second angle is about 30° greater than the first angle.
- 61. The valve plate assembly of claim 59, wherein the second angle is about 20° greater than the first angle.
- 62. The valve plate assembly of claim 57, wherein the first angle is greater than the second angle.
- 63. The valve plate assembly of claim 62, wherein the first angle is between about 10° and about 30° greater than the second angle.
- 64. The valve plate assembly of claim 63, wherein the first angle is about 30° greater than the second angle.
- 65. The valve plate assembly of claim 63, wherein the first angle is about 20° greater than the second angle.
- 66. A multi-cylinder compressor, comprising:
a valve plate comprising a plurality of cylinder suction ports formed therethrough, wherein at least one of the suction ports has a diameter greater than about 6 mm and less than about 14 mm; a plurality of cylinder bores; and a suction chamber having a substantially annular shape and adapted to be in fluid communication with each of the cylinder bores via the suction ports, wherein the suction chamber has a varying radius, and a mean radius of the suction chamber is greater than about 46 mm and less than about 54 mm.
- 67. The compressor of claim 66, wherein the diameter of the suction port is about 6 mm and the mean radius of the suction chamber is about 48 mm.
- 68. The compressor of claim 66, wherein the diameter of the suction port is about 8 mm and the mean radius of the suction chamber is about 48 mm.
- 69. The compressor of claim 66, wherein the diameter of the suction port is about 10 mm and the mean radius of the suction chamber is about 48 mm.
- 70. The compressor of claim 66, wherein the diameter of the suction port is about 12 mm and the mean radius of the suction chamber is about 48 mm.
- 71. The compressor of claim 66, wherein the diameter of the suction port is about 14 mm and the mean radius of the suction chamber is about 48 mm.
- 72. The compressor of claim 66, wherein the diameter of the suction port is about 14 mm and the mean radius of the suction chamber is about 46 mm.
- 74. The compressor of claim 66, wherein the diameter of the suction port is about 14 mm and the mean radius of the suction chamber is about 50 mm.
- 74. The compressor of claim 66, wherein the diameter of the suction port is about 14 mm and the mean radius of the suction chamber is about 52 mm.
- 75. The compressor of claim 66, wherein the diameter of the suction port is about 14 mm and the mean radius of the suction chamber is about 54 mm.
- 76. The compressor of claim 66, wherein the diameter of the suction port is about 12 mm and the mean radius of the suction chamber is about 46 mm.
- 77. A method of designing a multi-cylinder compressor comprising a valve plate comprising a plurality of cylinder suction ports formed therethrough, a plurality of cylinder bores, a suction chamber having a substantially annular shape and adapted to be in fluid communication with each of the cylinder bores via the suction ports, wherein the suction chamber has a varying radius, and a suction gas inlet passage connected to the suction chamber, comprising the steps of:
selecting an operating speed for the compressor; selecting a depth for the suction chamber; selecting a width for the suction chamber; selecting a first mean radius for the suction chamber; selecting a first diameter for the suction gas inlet passage; determining a frequency response of a mass flow rate of fluid within the suction chamber; and subsequently determining a first dynamic pressure response within the suction chamber using the frequency response of the mass flow rate of the fluid within the suction chamber.
- 78. The method of claim 77, further comprising the steps of:
changing the first mean radius to a second mean radius for the suction chamber; and determining a second dynamic pressure response within the suction chamber using the frequency response of the mass flow rate of the fluid within the suction chamber.
- 79. The method of claim 77, further comprising the steps of:
changing the first diameter to a second diameter for the suction gas inlet passage; and determining a second dynamic pressure response within the suction chamber using the frequency response of the mass flow rate of the fluid within the suction chamber.
- 80. The method of claim 79, further comprising the steps of:
changing the first mean radius to a second mean radius for the suction chamber; and determining a third dynamic pressure response within the suction chamber using the frequency response of the mass flow rate of the fluid within the suction chamber.
- 81. The method of claim 80, further comprising the steps of:
selecting a mean radius for the suction chamber, wherein the selected mean radius is one of the first mean radius and the second mean radius; and selecting a diameter for the suction gas inlet passage, wherein the selected diameter is one of the first diameter and the second diameter, wherein the mean radius and the diameter are selected based on the first dynamic pressure response, the second dynamic pressure response, and the third dynamic pressure response.
- 82. The method of claim 81, wherein the selected diameter is greater than about 6 mm and less than about 14 mm, and the selected mean radius is greater than about 46 mm and less than about 54 mm.
- 83. The method of claim 82, wherein the predetermined operating speed is about 1000 revolutions per minute, the predetermined width is about 12 mm, and the predetermined depth is about 28 mm.
Parent Case Info
[0001] This application claims the benefit of U.S. Provisional Patent Application No. 60/407,978, filed Sep. 5, 2002, which is incorporated herein by reference.
Provisional Applications (1)
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Number |
Date |
Country |
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60407978 |
Sep 2002 |
US |