Oil supply for integrated drive generator

An integrated drive generator oil supply (50) for providing pressurized oil to a constant speed drive transmission which drives a rotor (40) of an alternating current generator at a constant velocity to generate constant frequency alternating current and to at least one additional apparatus requiring pressurized oil and discharging oil into an oil reservoir during generation of the alternating current in accordance with the invention includes a pump (16) for providing pressurized oil from the oil circuit (28) for providing pressurized oil from the pump to an oil cooling circuit (100) within the alternating current generator for cooling the alternating current generator; an oil circuit (105) for providing oil directly from oil discharged from the oil cooling circuit to at least a part of the constant speed drive transmission which after lubricating the constant speed drive transmission is discharged into the oil reservoir.

CROSS REFERENCE TO RELATED APPLICATION 
Reference is made to patent application Ser. No. 324,752, pending entitled 
"Oil Management Tank System" filed on even date herewith. 
TECHNICAL FIELD 
The present invention relates to oil supplies for integrated drive 
generators used for generating constant frequency alternating current on 
airframes. More particularly, the present invention relates to oil 
supplies for integrated drive generators having reduced weight. 
BACKGROUND ART 
Integrated drive generators have been in use for many years in generating 
electrical power on airframes. An integrated drive generator functions to 
produce three phase 400 Hz. alternating current when driven by a variable 
speed power takeoff from the airframe propulsion engine. The integrated 
drive generator is contained in a single case which contains a constant 
speed drive transmission which converts the variable speed shaft input 
from the power takeoff from the airframe propulsion engine to a constant 
speed drive for driving an alternating current generator mounted within 
the case of the integrated drive generator. The constant speed drive 
transmission includes critical elements which require pressurized oil 
during the generation of alternating current by the integrated drive 
generator. These units include a hydraulic pump and motor, differential, 
cooling for the main generator and lubrication of the rotor of the main 
generator. All of these elements operate in a conventional fashion as is 
known in the art which does not form part of the present invention. 
FIG. 1 illustrates a block diagram of a prior art oil supply system for an 
integrated drive generator of the type manufactured by the assignee of the 
present invention. The integrated drive generator 10 has a case (not 
illustrated) which collects oil in an oil sump 12 located in the bottom of 
the case. The oil sump 12 supplies oil which is pressurized and applied to 
various parts of the integrated drive generator as described below. A 
scavenge pump 14 pressurizes oil from the oil sump 12 and applies it to a 
filter and deaerator (not illustrated). The output of the deaerator, which 
contains oil of higher quality than that pumped by the scavenge pump 14, 
is applied to the intake of charge pump 16. A charge pump 16 functions to 
pressurize the oil with a head such as 250 psi. The output of the charge 
pump 16 is applied to an oil circuit 18 which contains a plurality of 
parallel branches 20, 22, 24, 26 and 28. Branch 20 supplies pressurized 
oil to a hydraulic pump and motor 30 which is a conventional part of the 
constant speed drive transmission contained in the integrated drive 
generator. Branch 22, which contains a restriction 32, provides a bypass 
around the hydraulic pump and motor to permit the bypassing of oil around 
the hydraulic pump and motor instead of requiring that all oil being 
applied to charge relief valve 34 must flow through the hydraulic pump and 
motor 30. Charge relieve valve 34 controls the output pressure of oil in 
the oil circuit 18 by shunting oil back to the intake of charge pump 16 
when the pressure of oil outputted by the charge pump is above the limit 
at which the charge relief valve opens. Branch 24 applies pressurized oil 
to differential 36 which is part of the conventional constant speed drive 
transmission contained within the integrated drive generator. Oil from the 
differential 36 is outputted to the main sump 12. Branch 26 applies 
pressurized oil to the back iron of the main generator stator 38. The back 
iron of the stator 38 contains channels through which oil flows to cool 
the main generator in a conventional fashion. Oil is outputted from the 
oil cooling circuit of the stator 38 to oil sump 12. Pressurized oil in 
branch 28 cools the main generator rotor 40 and is applied to the bearings 
of the rotor to provide lubrication for the bearings rotatably supporting 
the rotor. Oil is outputted from the bearings of the main generator to the 
oil sump 12. 
While an oil circuit generally similar to that illustrated in FIG. 1 has 
worked satisfactorily in airframes, it has the disadvantage of requiring a 
scavenge pump 14 and charge pump 16 which are sized to satisfy the 
parallel oil flow requirements of the hydraulic pump and motor 30, 
differential 36, main generator stator 38 and main generator rotor 40. As 
a consequence of the oil flow requirements for supplying pressurized oil 
to the parallel oil circuits of the hydraulic pump and motor 30, 
differential 36, main generator stator 38 and main generator rotor 40, the 
overall capacity of the charge pump must be rated to exceed the cumulative 
maximum oil capacity which may be drawn by each of the aforementioned 
units within the integrated drive generator. Furthermore, in order to 
preclude any possibility of starving the charge pump 16 of oil, the 
scavenge pump 14 must be sized to provide a larger oil flow to the intake 
of the charge pump, such as 150% of the rated output of the charge pump. 
As a result, the parallel oil flow circuits 20, 24, 26 and 28, which 
respectively provide oil to the hydraulic pump and motor 30 differential 
36, main generator stator 38 and main generator rotor 40, require the 
scavenge pump 14 and charge pump 16 to be large enough to satisfy the 
aforementioned oil flow requirements. 
Any reduction in the overall rated output of the charge pump results in a 
weight savings in the integrated drive generator in that the charge pump 
may be downsized and further the scavenge pump may be downsized even 
further as a result of its having a rated output higher than the rated 
output of the charge pump. Reduction in pump size also enhances the 
overall efficiency of the integrated drive generator. 
DISCLOSURE OF INVENTION 
The present invention provides an integrated drive generator oil supply 
which is lighter in weight than the prior art illustrated in FIG. 1. The 
weight saving achieved by the present invention is of particular 
significance given the preferred application of the present invention as 
being for generating constant frequency alternating current in airframes. 
An integrated drive generator oil supply for providing pressurized oil to a 
constant speed drive transmission, which drives a rotor of an alternating 
current generator at a constant velocity to generate constant frequency 
alternating current, and to at least one additional apparatus requiring 
pressurized oil and discharging oil into an oil reservoir during 
generation of alternating current in accordance with the invention 
includes a pump for providing pressurized oil from the oil reservoir of 
the integrated drive generator; an oil circuit for providing pressurized 
oil from the pump to an oil circuit within the alternating current 
generator for cooling the alternating current generator; and an oil 
circuit for providing pressurized oil directly from oil discharged from 
the oil cooling circuit to at least a part of the constant speed drive 
transmission which after lubricating the constant speed drive transmission 
is discharged into the reservoir. The pump is a charge pump; the constant 
speed drive transmission comprises a differential which receives 
pressurized oil from the oil circuit for cooling the alternating current 
generator and discharges oil into the oil reservoir; and the oil circuit 
for cooling the alternating generator is disposed in the stator of the 
alternating current generator. The constant speed drive transmission 
further comprises a hydraulic pump and motor which receives pressurized 
oil from the charge pump and returns oil to an intake of the charge pump. 
The at least one additional apparatus comprises bearings rotatably 
supporting a rotor of the alternating current generator which receive 
pressurized oil from the charge pump and which discharge oil into the oil 
reservoir and a rotor cooling oil circuit which discharges oil into the 
oil reservoir. 
The reservoir comprises an oil tank contained within the integrated drive 
generator and an oil sump contained within a case of the integrated drive 
generator; the bearings discharge oil into the oil sump and the rotor 
cooling oil circuit discharges oil into the oil tank; and the differential 
discharges oil into the oil sump. An additional pump provides pressurized 
oil to an inlet of the charge pump from the oil reservoir. 
An integrated drive generator oil supply for providing pressurized oil to a 
stator of the alternating current generator and to a differential of a 
constant speed drive transmission which drives a rotor of an alternating 
current generator at a constant velocity to generate constant frequency 
alternating current in accordance with the invention includes a scavenge 
oil pump for providing pressurized oil at an output from an oil reservoir 
within the integrated drive generator; a charge oil pump having an intake 
coupled to the output of the scavenge pump for providing pressurized oil 
at an output; an oil circuit for providing pressurized oil from the output 
of the charge pump to an oil cooling circuit within a stator of the 
alternating current generator; and an oil circuit for providing oil 
discharged from the oil cooling circuit directly to the differential of 
the constant speed drive for lubricating the differential which discharges 
the lubricating oil into the oil reservoir. The oil supply further 
comprises at least one additional apparatus requiring pressurized oil and 
discharging oil into the oil reservoir during generation of the 
alternating current; and an oil circuit for providing pressurized oil from 
the output of the charge pump to the at least one additional apparatus. 
The at least one additional apparatus comprises a rotor of the alternating 
current generator. The constant speed drive transmission further comprises 
a hydraulic pump and hydraulic motor for receiving pressurized oil from 
the charge pump and discharging oil at the intake of the hydraulic motor. 
In an oil supply of an integrated drive generator having a scavenge pump 
for applying pressurized oil from an oil reservoir within the integrated 
drive generator to a charge pump which supplies pressurized oil at an 
output to a plurality of apparatus disposed within the integrated drive 
generator during the generation of constant frequency alternating current 
by a main generator located within the integrated drive generator, an 
improvement in accordance with the present invention comprises a series 
oil circuit having an intake coupled to the output of the charge pump, 
containing at least two of the plurality of apparatus with each of the 
apparatus being in series so that oil flowing within the series circuit 
flows sequentially through the at least two apparatus and a discharge 
which discharges oil after flowing through the at least two apparatus into 
the oil reservoir.

BEST MODE FOR CARRYING OUT THE INVENTION 
FIG. 2 illustrates a block diagram of an embodiment 50 in accordance with 
the present invention. Like reference numerals identify like parts in 
FIGS. 1 and 2. The functions of like parts in FIGS. 1 and 2 will not be 
discussed herein except to the extend necessary to understand the present 
invention with it being understood that those parts whose function is not 
discussed operate in the same manner as described above with reference to 
the prior art of FIG. 1. The present invention achieves a reduced weight 
oil supply for an integrated drive generator by utilization of a series 
oil circuit 52 which connects pressurized oil outputted from the charge 
pump 16 to at least two apparatus within the integrated drive generator 
requiring pressurized oil during the generation of constant frequency 
alternating current so that oil flowing within the series circuit flows 
sequentially through the at least two apparatus and is discharged by a 
discharge after flowing through the at least two apparatus into a 
reservoir within the integrated drive generator which may be the oil sump 
or an oil tank described below. By providing the series circuit 52, the 
overall rated output capacity of the scavenge pump 14 and charge pump 16 
is reduced as a consequence of the oil flow requirement of the apparatus 
located in the series oil circuit being satisfied by sequential oil flow 
instead of by all apparatus requiring pressurized oil during the 
generation of alternating current with parallel oil flow which increases 
the required rated output capacities of the charge pump and scavenge pump 
in the prior art. Accordingly, the overall weight of the oil supply 50 of 
an integrated drive generator in accordance with the embodiment of FIG. 2 
is reduced by downsizing the scavenge pump 14 and charge pump 16 pumping 
capacities to supply the requisite rated oil flows to the oil circuit 
which includes a combination of parallel and series oil flow. 
In the preferred form of the present invention, a cooling oil circuit 
disposed within the back iron of the main generator stator 38 is connected 
directly to the output of the charge pump 16. The pressurized oil from the 
charge pump 16 flows through the cooling oil circuit within the back iron 
of the main generator stator 38 and is discharged directly into the 
differential of the constant speed drive transmission which functions to 
drive the rotor 40 of the main generator at constant velocity to generate 
constant frequency alternating current. The oil directly applied from the 
output of the cooling oil circuit of the main generator 38 to the 
differential 36 functions to lubricate the differential in a conventional 
manner and is discharged to the oil sump 12. 
FIG. 3 illustrates a block diagram of a preferred embodiment 60 of the 
present invention. Like reference numerals identify like parts in FIGS. 
1-3. The function of parts illustrated in FIG. 3, which function in a 
manner identical to that described above with respect to the prior art of 
FIG. 1, will not be herein described except to the extent necessary to 
understand the operation of the embodiment illustrated in FIG. 3. Power 
takeoff 62, which is driven at variable speed by the airframe propulsion 
engine, applies torque to the hydraulic pump and motor 30 and the 
differential 36. The differential 36 has a constant speed output 64 which 
drives the rotor 40 at constant velocity to cause constant frequency 400 
Hz. three phase alternating current to be generated. The aforementioned 
operation is conventional. Case 66 closes the entire integrated drive 
generator 60 and forms the oil sump 12 which has been illustrated 
schematically. An inversion pump 66 functions to pump oil from the sump 12 
when the integrated drive generator is inverted or is at a steep angle 
near inversion in flight with respect to its normal horizontal inclination 
in the same manner as the scavenge pump 14 pumps oil when the integrated 
drive generator is in its normal horizontal or inclined inclination. The 
combination of the scavenge pump 14 and inversion pump 67 prevents 
apparatus from being damaged which require a critical supply of 
pressurized oil for operation. The output of the scavenge pump 14 and 
inversion pump 67 is applied to filter 68 which functions to remove any 
particulate matter entrained in the oil pumped by the scavenge pump 14 or 
inversion pump 67. The switch 70 provides an indication to the cockpit of 
the airframe when filter 68 is plugged. Indicator 72 provides a visual 
indication to maintenance personnel when the filter 68 is plugged. Oil 
pumped from the filter is pumped outside of the case 66 to heat exchanger 
74 to cool the oil prior to application to deaerator 76. Relief valve 78 
provides a bypass to the heat exchanger if the pressure drop in the heat 
exchanger is too high. Dynamic tank 80 provides a second portion of an oil 
reservoir within the integrated drive generator 60 with the sump 12 
providing the other portion of the oil reservoir. The function of the 
dynamic tank 80 is dual fold in that various oil flows to the tank 
including an output from the deaerator 76 maintain the tank full to reduce 
the overall level of oil within the sump 12 of case 66. Furthermore, if 
for some reason the output from the deaerator 76 is insufficient to supply 
the requisite flow of oil to the intake of charge pump 16 during normal 
level or banked but non-inverted flight, oil flows from the dynamic tank 
80 into the input of the charge pump 16 to make up for any deficiency in 
the output of oil from the deaerator necessary to maintain the requisite 
amount of oil flow to the charge pump to prevent starving oil critical 
apparatus from pressurized oil outputted from the charge pump. Dual port 
relief valve 82 functions to provide oil to the dynamic tank 80 from the 
output of the scavenge pump 14 and the inversion pump 67 when the output 
pressure from the scavenge pump 14 or inversion pump 12 exceed a 
predetermined pressure limit at which the relief valve opens. However, 
under cold starting conditions, the dual port relief valve 82 diverts oil 
back to the intake of the scavenge pump 14. The dynamic tank 80 has a 
drain 84 in the top which permits oil to flow out of the tank when the net 
oil flow into the tank is sufficient to maintain the tank above the full 
level. Drain 86 permits debris and other matter to be drained from the 
bottom of the dynamic tank. The dynamic tank 80 also receives scavenge 
pump leakage 88, charge pump leakage 90, oil from aspirator 92 which 
functions in a conventional manner to remove water from the oil within the 
integrated drive generator. Maintaining the tank full during generation of 
alternating current reduces the level of oil in the oil sump 12 which 
lessens the possibility of thermal runaway and increases the efficiency of 
the operation of the equipment within the integrated drive generator by 
reducing mechanical drag consequent from high oil levels. The charge pump 
applies pressurized oil to governor 94 which controls the position of 
control piston 96 which varies the angle of the swash plate of the 
hydraulic pump. Relief valve 98 opens to apply pressurized hydraulic fluid 
directly to the differential 36 when the output of the cooling circuit 100 
within the stator has oil pressure dropped below a predetermined pressure. 
Typically the relief valve 98 opens with a pressure of 150 psi with the 
charge relief valve 34 opening at a pressure of 250 psi. 
The series oil circuit 52 has an input 102 connected to the output of the 
charge pump 16. Oil flows from the input 102 to the oil cooling circuit 
100 which is located in the back iron of the stator 38. The cooling 
circuit 100 is of conventional construction and causes oil to flow 
helically through the back surface of the stator 38 to cool the stator. 
The output 104 of the cooling oil circuit 100 is applied by oil circuit 
105 directly to the input 106 of the differential 36. The oil applied to 
the input 106 of the differential 36 functions to lubricate the 
differential and is discharged to the oil sump at outputs 108 and 110. 
Furthermore, the circuit 28 for the rotor 40 is in parallel to the series 
circuit 52 and functions to supply oil for lubricating bearings rotatably 
supporting the rotor and further to an oil cooling circuit flowing axially 
through the rotor. Similarly, the branch 20 has input 112 connected 
directly to the output of the charge pump 16 and output 114 connected to 
the charge relief valve 34 to configure the branch 20 in parallel with the 
oil supplied to the rotor 40. 
While the invention has been described in terms of its preferred 
embodiment, it should be understood that numerous modifications may be 
made thereto without departing from the spirit and scope of the invention 
as defined in the appended claims. It is intended that all such 
modifications fall within the scope of the appended claims.