The present invention relates to an environmental control system. In particular, the invention relates to a ram air fan assembly for an environmental control system for an aircraft.
An environmental control system (ECS) aboard an aircraft provides conditioned air to an aircraft cabin. Conditioned air is air at a temperature, pressure, and humidity desirable for aircraft passenger comfort and safety. At or near ground level, the ambient air temperature and/or humidity is often sufficiently high that the air must be cooled as part of the conditioning process before being delivered to the aircraft cabin. At flight altitude, ambient air is often far cooler than desired, but at such a low pressure that it must be compressed to an acceptable pressure as part of the conditioning process. Compressing ambient air at flight altitude heats the resulting pressurized air sufficiently that it must be cooled, even if the ambient air temperature is very low. Thus, under most conditions, heat must be removed from air by the ECS before the air is delivered to the aircraft cabin. As heat is removed from the air, it is dissipated by the ECS into a separate stream of air that flows into the ECS, across heat exchangers in the ECS, and out of the aircraft, carrying the excess heat with it. Under conditions where the aircraft is moving fast enough, the pressure of air ramming into the aircraft is sufficient to move enough air through the ECS and over the heat exchangers to remove the excess heat.
While ram air works well under normal flight conditions, at lower flight speeds, or when the aircraft is on the ground, ram air pressure is too low to provide enough air flow across the heat exchangers for sufficient heat removal from the ECS. Under these conditions, a fan within the ECS is employed to provide the necessary airflow across the ECS heat exchangers. This fan is called a ram air fan.
As with any system aboard an aircraft, there is great value in an improved ram air fan that includes innovative components designed to improve the operational efficiency of the ram air fan or to reduce its weight.
A tie rod for extending between a fan shroud and a shaft cap in a rotative assembly includes a first end with threads; a second end with threads; and an elongated portion between the first end and the second end. The tie rod has diameter to length ratio of about 1 to 40.810 to about 1 to 40.768.
A method of installing a tie rod into a ram air fan rotative assembly includes connecting a motor rotor, thrust shaft, fan rotor, inlet shroud, bearing shaft and a shaft cap; placing the tie rod through the shaft cap and through the inlet shroud; stretching the tie rod; fastening a nut on threads of a first end of the tie rod; fastening a nut on the threads of the second end of the tie rod; and releasing the stretch on the tie rod.
As illustrated in
In operation, ram air fan assembly 10 is installed into an environmental control system aboard an aircraft and connected to the fan inlet, the bypass inlet, and the fan outlet. When the aircraft does not move fast enough to generate sufficient ram air pressure to meet the cooling needs of the ECS, power is supplied to motor stator 26 by wires running from terminal box 46, through wire transfer tube 54, inner housing 20, and bearing housing 14.
Energizing motor stator 26 causes rotor 25 to rotate about the axis of rotation of ram fan assembly 10, rotating rotative assembly 21. Motor rotor 25 rotates connected journal bearing shaft 34 and thrust shaft 28. Fan rotor 42 and inlet shroud 44 also rotate by way of their connection to thrust shaft 28. Tie rod 38 ensures that rotative assembly 21 rotates uniformly together by connecting to inlet shroud 44 and to shaft cap 36 of rotative assembly 21. Journal bearings 40 and thrust bearings 32 provide low friction support for the rotating components. As fan rotor 42 rotates, it moves air from the fan inlet, through inlet housing 20, past fan struts 22 and into the space between fan housing 12 and outer housing 18, increasing the air pressure in outer housing 18. As the air moves through outer housing 18, it flows past diffuser 50 and inner housing 20, where the air pressure is reduced due to the shape of diffuser 50 and the shape of inner housing 20. Once past inner housing 20, the air moves out of outer housing 18 at the fan outlet. Components within bearing housing 14 and fan housing 12, especially thrust bearings 32, journal bearings 40, motor stator 26, and motor rotor 24; generate significant heat and must be cooled. Cooling air is provided by motor bearing cooling tube 52 which directs a flow of cooling air to inner housing 20. Inner housing 20 directs flow of cooling air to bearing housing 14, where it flows past components in bearing housing 14 and fan housing 12, cooling the components. Once the aircraft moves fast enough to generate sufficient ram air pressure to meet the cooling needs of the ECS, ram air is directed into plenum 48 from the bypass inlet. The ram air passes into outer housing 18 at plenum 48 and moves out of outer housing 18 at the fan outlet.
Fan inlet shroud 44 is connected to tie rod 38 at first end 56. Nut 60 connects to tie rod 38 adjacent to inlet shroud 44. Inlet shroud connects to fan rotor 42, which connects to thrust shaft 28 Thrust shaft 28 connects to motor rotor 25, which connects to journal bearing shaft 34. Journal bearing shaft 34 connects securely to shaft cap 36, which connects to second end 58 of tie rod 38. Second nut 62 secures to second end 58 of tie rod 38 adjacent to shaft cap 36.
When ram air fan 10 is in operation, thrust shaft 28, journal bearing shaft 34, shaft cap 36, tie rod 38, fan rotor 42 and inlet shroud 44 all rotate together. Tie rod 38 connects the ends of rotative assembly 21 (inlet shroud 44 and shaft cap 36) with a pre-load force to ensure secure connections between all parts of rotative assembly 21. These secure connections work to guarantee uniform rotation between parts of rotative assembly 21. Simultaneous rotation is essential to ensure that rotative assembly 21 is functioning properly as well as to extend the life of parts of rotative assembly 21. Parts are susceptible to degradation and wear when they are not rotating as one. The preload force on tie rod 38 can be about 4000 pounds.
Past systems generally included tie rods that had a central support connecting tie rod 38 to motor rotor 25 or shafts (34, 28). Tie rod 38 of the current invention is dimensioned so that no additional supports are needed, saving weight and cost of adding supports in rotative assembly 21. Additionally, the lack of need for another support ensures tie rod 38 does not block cooling flow through rotative assembly 21.
On first end 56 of tie rod 38, threads 57 extend a length of threads LT of about 0.97 inches (24.638 mm) to about 1.03 inches (26.162 mm) from first end 56. Portion 66 for fan inlet shroud 44 connection can be about 0.5 inches (12.7 mm) axially and go from about 2.0 inches (50.8 mm) to about 2.5 inches (63.5 mm) from first end 56. Total length L of tie rod 38 from first end 56 to second end 58 can be about 15.06 inches (382.524 mm) to about 15.12 inches (384.048 mm). Diameter D of tie rod can be about 0.3695 inches (9.385 mm) to about 0.3705 inches (9.411 mm). On second end 58 of tie rod 38 threads 59 extend axially about 0.97 inches (24.638 mm) to about 1.03 inches (26.162 mm) from end 58. Portion 68 for shaft cap 36 connection can be about 0.5 inches (12.7 mm) axially and go from about 2.0 inches (50.8 mm) to about 2.5 inches (63.5 mm) from second end 58. Length LE of elongated portion between portion 66 and portion 68 can be about 10.06 inches (255.524 mm) to about 10.12 inches (257.048 mm). Unthreaded length LU of tie rod 38 can be about 13.06 inches (331.724 mm) to about 13.12 inches (333.248 mm). The diameter to length ratio of tie rod 38 can be about 1:40.810 to about 1:40.768.
As mentioned above, tie rod 38 is dimensioned with a specific length L, unthreaded length LU, length LE between portions (66, 68) to shaft cap 36 and inlet shroud 44 and diameter D so that no additional supports are needed for tie rod 38. Specific dimensions, including a unique length L to diameter D ratio, are also carefully selected to prevent tie rod 38 from having resonant modes within system operating ranges. Rotating machinery, such as ram air fans, have specific operating ranges, for example 20,000 RPM. If the frequency at which rotative assembly 21 is spinning is the same frequency as a system operating mode, tie rod 38 will resonate and vibrate. This vibration introduces unbalance into rotative assembly 21, placing high loads onto rotative assembly 21 parts and bearings 32, 40. These high loads can cause degredation of parts and possible part failures.
Shaft cap 36 connects securely to shaft 34 at pilot 74 through an interference fit (the outer diameter of pilot 74 is larger than the inner diameter of shaft 34). Shaft cap 36 connects to tie rod 38 at circular portion 70. Nut 62 threads on tie rod 38 to securely hold shaft cap 36 on tie rod 38. When ram air fan 10 is in operation, tie rod 38, shaft cap 36 and shaft 34 rotate together. This simultaneous rotation is essential to ensure the rotative assembly 21 is functioning properly as well as to extend the life of parts of rotative assembly 21. Parts are susceptible to degradation and wear when they are off balance and do not rotate together.
Making shaft cap 36 separately from shaft 34 allows for a less expensive and easier manufacturing process. Past systems manufactured shaft 34 and shaft cap 36 as one part. Due to the complex geometry, machining shaft with holes and cap section with a conical portion and central hole for a tie rod was very difficult and costly. Machining shaft cap 36 and shaft 34 separately and using an interference fit to secure them together results in parts that are easier and less expensive to make while still having a strong connection to rotate together under system operating conditions.
Machining shaft cap 36 separately also allows for the machining of a more angled conical section (than could be made if cap 36 and shaft 34 were machined as one part). As mentioned in relation to
Radial distance DI between center axis of shaft cap 36 and edge of inner portion 80 can be about 1.5655 inches (39.764 mm) to about 1.5665 inches (39.789 mm). Radial distance DO between center axis of shaft cap 36 and edge of outer lip 76 (or conical section 72) can be about 1.759 inches (44.679 mm) to about 1.761 inches (44.729 mm). Radial distance DO between center axis of shaft cap 36 and edge of outer lip 76 (or conical section 72) can be about 1.759 inches (44.679 mm) to about 1.761 inches (44.729 mm). Angle AC of conical section can be about 48 degrees to about 52 degrees. Angle A1 between outer lip 76 and undercut portion 78 of pilot 74 can be about 43 degrees to about 47 degrees. Radius RU of undercut portion 78 can be about 0.035 inches (0.889 mm) to about 0.045 inches (1.143 mm). Depth DU of undercut portion 78 can be about 0.042 inches (1.067 mm) to about 0.052 inches (1.321 mm). Axial distance Dp between outer lip 76 and end of inner portion 80 can be about 0.265 inches (6.731 mm) to about 0.275 inches (6.985 mm). Axial distance of slanted edge D2; can be about 0.030 inches (0.762 mm). Angle A2 of slanted edge at inner portion 80 of pilot 74 can be about 28 degrees to about 32 degrees.
Dimensions of pilot 74 are key to providing an interference connection between shaft cap 36 and shaft 34 under all operating conditions. Dimensions must be precise, as system operating conditions can range from temperatures of about negative 65 degrees F. up to about 200 degrees F. These extreme temperature changes can cause shaft cap 36 to expand or contract slightly, but must not affect the connection between shaft 34 and shaft cap 36. Undercut portion 78 is a semi-circular recess around the pilot 74, and acts as a stress relief in the connection between shaft 34 and shaft cap 36. Undercut 78 ensures that the interference fit does not cause pilot 74 to crack when shaft cap 36 may expand under high operating temperatures.
Connecting the shaft cap to the shaft with an interference fit (step 83) can be done by first shrinking shaft cap, for example by immersing shaft cap 36 in liquid nitrogen, causing shaft cap 36 to freeze and contract or by utilizing a hydraulic press. Then shaft cap 36 is placed in an end of shaft 34 so that inner portion 80 and undercut portion 78 of pilot 74 are inside shaft 34. Slanted edge 79 can assist in easing shaft cap 36 into shaft 34. Shaft cap 36 is then allowed to expand and return to its normal state to form a secure connection with shaft 34. Step 83 forms a secure connection between shaft cap 36 and shaft 34 due to the outer diameter of inner portion 80 of shaft cap 36 being larger than the inner diameter of shaft 34. Thus, shaft cap 36 connects securely to shaft and rotates with shaft 34 when ram air fan 10 is in operation.
Connecting motor rotor 25, thrust shaft 28, fan rotor 42, inlet shroud 44, bearing shaft 34 with shaft cap 36 (step 84) can be done with various connections such as interference fit connections, bolts or other methods. Connections must be secure so that all parts rotate together.
Next, tie rod 38 is placed through shaft cap 36 and through inlet shroud 44 (step 86) before stretching the tie rod (step 88). Tie rod 38 can be stretched using a machine that pulls on first end 56 and second end 58.
Fastening nut 60, 62 on threads on first end 56 of the tie rod 38 (step 90) and on second end 58 of the tie rod 38 (step 92) and releasing the stretch on the tie rod (step 94) secures the pre-load on tie rod 38. The pre-load on tie rod 38 clamps together parts of rotative assembly 21 to ensure secure connections and promote uniform rotation of rotative assembly 21.
The steps of stretching tie rod 38 (step 96); tightening nuts 60, 62 on the first and second ends of the tie rod 38 (step 98); and releasing the stretch on tie rod 38 (step 100) can be performed a second time to add more preload to tie rod 38.
In summary, tie rod 38 includes specific dimensions to be able to extend the length of rotative assembly 21 without needing additional support. Tie rod 38 dimensions, including a unique length L to diameter D ratio, also work to prevent tie rod resonant modes in ram air fans' operating range, ensuring efficient operation of rotative assembly 21 and a good working life of parts of rotative assembly 21.
While the invention has been described with reference to exemplary embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. For example, dimensions can be modified depending on system requirements. Therefore, it is intended that the invention not be limited to the particular embodiment(s) disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.
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