This application is the US National Stage of International Application No. PCT/EP2010/052336, filed Feb. 24, 2010 and claims the benefit thereof. The International Application claims the benefits of European application No. 09154259.7 EP filed Mar. 3, 2009. All of the applications are incorporated by reference herein in their entirety.
This invention relates to an apparatus comprising a shaft and a balancing sleeve.
The invention finds application in a mechanical drive apparatus comprising a coupling shaft for coupling a driver unit at a first end of the shaft to a driven unit at a second end of the shaft, in use of the apparatus the driver unit rotating the shaft to drive the driven unit.
It can be difficult to balance the coupling shaft at both lower and higher speeds of rotation due to flexibility of the shaft. This will now be explained with reference to
In
For balance of the shaft 3, the centrifugal force CFbal1 acting on flange 5 (as a result of its eccentricity) times the distance a+b from flange 5 to flange 7 must equal the centrifugal force CFdisc acting on disc 1 (as a result of its eccentricity) times the distance b from disc 1 to flange 7, i.e.
CFbal1.(a+b)=CFdisc.b (Equation 1),
or
Mbal.ebal.w2.(a+b)=Mdisc.edisc.w2.b (Equation 2),
where Mbal is the mass of flange 5, Mdisc is the mass of disc 1, and w2 is the angular velocity of rotation squared.
This gives:
Mbal.ebal =(b/(a +b)).Mdisc.edisc (Equation 3),
i.e. for balance the mass of balancing flange 5 times the eccentricity of flange 5 must equal b/(a +b) times the mass of disc 1 times the eccentricity of disc 1.
Equation 3 maintains balance at lower speeds of rotation, but at higher speeds an increase in CFdisc (due to the increase in speed) causes flexing of the shaft 3 as shown in
According to the present invention there is provided an apparatus comprising a shaft mounted for rotation and a balancing sleeve for balancing the shaft during rotation, the balancing sleeve having first and second ends, the first end being secured to the shaft so that the balancing sleeve is substantially concentric with the shaft and rotates with the shaft, the second end incorporating balancing weight to balance the shaft at lower speeds of rotation of the shaft where there is substantially no flexing of the shaft, wherein the lengthwise stiffness of the balancing sleeve is matched to the lengthwise stiffness of the shaft to maintain balance of the shaft at higher speeds of rotation of the shaft where there is flexing of the shaft.
The invention will now be described, by way of example, with reference to the accompanying drawings, in which:
Referring to
As before, at higher speeds, there will be a displacement d of disc 1, but this time, due to flexing of balancing sleeve 11, there will also be a displacement y of the balancing weight at the free end of sleeve 11 in the opposite direction to displacement d. This compensates for displacement d as will now be explained.
To maintain balance at higher speeds,
CFbal1.(a+b)=CFdisc.b (Equation 4),
or
Mbal.(ebal+y).w2.(a+b)=Mdisc.(edisc+d).w2.b (Equation 5).
Subtracting Equation 2 from Equation 5 gives:
Mbal.y.w2.(a+b)=Mdisc.d.w2.b (Equation 6),
or
Mbal.y=(b/(a+b)).Mdisc.d (Equation 7).
Now:
CFbal1=Sbal.y (Equation 8),
where Sbal is the stiffness of balancing sleeve 11, and
CFdisc=Sshaft.d (Equation 9),
where Sshaft is the stiffness of shaft 3.
Using Equations 8 and 9 to substitute for CFbal1 and CFdisc in Equation 1 gives:
Sbal.y.(a+b)=Sshaft.d.b (Equation 10),
or
(Sbal.y)/(Sshaft)=(b/(a+b)).d (Equation 11).
Using Equation 11 to substitute for (b/(a+b)).d in Equation 7 gives:
Mbal.y=Mdisc.(Sbal.y)/(Sshaft) (Equation 12),
or
Sbal=Sshaft.(Mbal/Mdisc) (Equation 13).
Thus, to maintain balance at higher speeds, the stiffness of the balancing sleeve 11 must be matched to that of the shaft 3 according to Equation 13.
As can be seen from Equation 13, in the simple case of
The choice of the stiffness of the balancing sleeve is made such that potential imbalance of the shaft at higher speeds due to flexing of the shaft is offset by potential opposite imbalance of the shaft at higher speeds due to flexing of the balancing sleeve (by potential opposite imbalance is meant the imbalance of the shaft that would occur at higher speeds due to flexing of the balancing sleeve if the shaft itself did not flex at all at higher speeds). In other words, imbalance of the shaft at higher speeds due to flexing of the shaft is countered by flexing of the balancing sleeve at these higher speeds.
Referring to
First end 27 of tube 21 includes a circumferential flange 31 that extends radially outwardly. First end 25 of sleeve 23 includes a circumferential flange 33 that extends radially inwardly. Circumferential flange 33 of sleeve 23 is secured between circumferential flange 31 of tube 21 and a driver unit 35.
Second end 29 of sleeve 23 includes a circumferential flange 37 that extends radially outwardly, and second end 29 incorporates balancing weight by the provision of trim balance holes 39 in circumferential flange 37. Trim balance holes 39 are tapped to allow weights to be screwed in as required.
Sleeve 23 may include axially extending slots 41 to reduce its lengthwise stiffness.
In accordance with the above description with reference to
Balancing sleeve 23 of
Referring to
First end 57 of tube 51 includes a circumferential flange 61 that extends radially outwardly. First end 55 of sleeve 53 includes a circumferential flange 63. Circumferential flange 61 of tube 51 is secured between circumferential flange 63 of sleeve 53 and a driver unit 65. Sleeve 53 is divided lengthwise into a pair of half sleeves 53a, 53b of semicircular cross-section.
A clamp bolt 67 extends between pair of half sleeves 53a, 53b at each lengthwise division to adjust (i) the positions of half sleeves 53a, 53b so that they are concentric with tube 51, and (ii) the size X, Y in the circumferential direction of the divisions so that X=Y.
Sleeve 53 comprising pair of half sleeves 53a, 53b includes at its second end 59 a unitary locking ring 69 that locks together pair of half sleeves 53a, 53b. Second end 59 of sleeve 53 incorporates balancing weight by the provision of trim balance holes 71 in locking ring 69. Trim balance holes 71 are tapped to allow weights to be screwed in as required.
Half sleeves 53a, 53b comprising sleeve 53 advantageously include axially extending slots (not shown) as slots 41 in
In accordance with the above description with reference to
Balancing sleeve 53 of
Balancing sleeve 53 of
Referring to
First end 87 of tube 81 includes a circumferential flange 91 that extends radially outwardly. Sleeve 83 comprises a rigid annular adaptor plate 93 adapted to be secured between circumferential flange 91 and a driver unit 115, a resilient annular disc 95 bolted to adaptor plate 93, and a rigid balancing tube 97 one end 99 of which is bolted to annular disc 95. Other end 101 of balancing tube 97 comprises second end 89 of sleeve 83. The lengthwise stiffness of sleeve 83 is determined by the resilience of annular disc 95.
One side 103 of annular adaptor plate 93 includes a first number of axially extending circumferentially spaced protrusions 105. One side 107 of resilient annular disc 95 is bolted to the ends of first protrusions 105. One end 99 of balancing tube 97 includes a second number of axially extending circumferentially spaced protrusions 109. Other side 111 of resilient annular disc 95 is bolted to the ends of second protrusions 109. The positions of attachment of first protrusions 105 to annular disc 95 are circumferentially intermediate the positions of attachment of second protrusions 109 to annular disc 95.
Second end 89 of sleeve 83 incorporates balancing weight by the provision of trim balance holes 113 in other end 101 of balancing tube 97. Trim balance holes 113 are tapped to allow weights to be screwed in as required.
Annular adaptor plate 93 may be unitary (cf.
Balancing sleeves 83 of different stiffness can be provided by varying the resilience of resilient annular disc 95. Trialling balancing sleeves 83 of different stiffness can be done by installing in turn annular discs 95 of different resilience, the exchange of one annular disc 95 for another being done whilst annular adaptor plate 93 remains secured between circumferential flange 91 of tube 81 and driver unit 115. Another way to trial balancing sleeves 83 of different stiffness would be to provide an annular disc 95 made up of several relatively thin annular discs, and to vary the stiffness by changing the number of constituent relatively thin annular discs.
In accordance with the above description with reference to
The flexing of balancing sleeve 83 of
In the first, second and third mechanical drive apparatus of
It is to be realised that the present invention is not only applicable to balancing a coupling shaft that couples a driver unit to a driven unit, but can be used to balance any rotating shaft, e.g. a rotating shaft of a turbine, a compressor, a motor or gearing.
Number | Date | Country | Kind |
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09154259 | Mar 2009 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP2010/052336 | 2/24/2010 | WO | 00 | 11/8/2011 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2010/100062 | 9/10/2010 | WO | A |
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Number | Date | Country | |
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20120094776 A1 | Apr 2012 | US |