6556K377 on McMaster was selected as the piston. The relevant dimensions and properties of 6556K377 are enumerated in the table below:
| Bore Diameter, Inner (in) | Bore Material | Stroke Length (in) | Rod Material | Rod Diameter (in) | Total Length (baseplate to baseplate; in) |
|---|---|---|---|---|---|
| 1-1/4 | Aluminum | 5.5 | Steel1 | 3/8-16 | 8.4 |
Given a 4.5" coupling section, this gives us a 1" margin on separation distance.
1 Specs for 303 stainless steel used below as estimate.
Buckling Calculation
We need to ensure that the rod of the piston will not buckle when it transfers load to the diaphragm. To perform these calculations we know that the tensile modulus of steel is 28000 ksi:
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Given the area moment of inertia for a circular cross section is:
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Pcr,steel = 12,789 lbs
As you can see, there is approximately a 35x factor of safety on rod buckling.
Burst Factor of Safety
Here we calculate the precise burst factor of safety on our piston. Some details:
- Aluminum 6061-T6 has a tensile yield strength of approximately 276 MPa = 40.03 ksi
- The inner radius of the piston bore is 0.625"
- The wall thickness is approximately 0.125"
The Design Space
Our redesigned piston must have the same form factor as a McMaster piston to allow for easy descope. Given the team's Fall 2017 semester experience with tie-rod pistons, we elect to continue using this style.
DTEG Requirements
As of 1/4/2018, the latest edition of the Spaceport America Cup's Design Test and Evaluation Guide has the following requirements for SRAD pressure vessels. These requirements can be read in more detail here (add link).
4.2.2 DESIGNED BURST PRESSURE FOR METALLIC PRESSURE VESSELS
4.2.4.1 PROOF PRESSURE TESTING
4.2.4.2 OPTIONAL BURST PRESSURE TESTING
You can find a complete list of DTEG requirements that affect the Recovery system on the Hermes Recovery System page.
Desired Performance
The piston must be able to supply enough force at its operating pressure to break the shear pins with a 2x safety factor, which is the safety-critical guideline for parachute components presented by NASA (Section 3.3.1.5). The same source (Section 3.3.1.6) dictates a design burst pressure factor of 2x the maximum design pressure, which aligns with DTEG requirement 4.2.2. [5] Then, to determine when the cylinder will burst, we make use of thin-walled pressure vessel theory [2], paraphrased below:
Neglecting end effects, the limiting factor will be the hoop stress in the piston bore:
Mathinline body \sigma_{hoop} = \frac{pR}{t}
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Mathinline body \sigma_{hoop} = \frac{pR}{t} = \frac{p*0.625in}{0.125 in} =
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40030 \frac{lb}{in^2}
Pburst = 8006 lb/in2
The necessary pressure for a separation of 360 pounds is calculated as follows:
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Psep = 362.17 lb/in2
This gives a ~22x factor of safety on burst.
Premature Separation Factor of Safety
Next we check the factor of safety on premature separation, knowing that as previously calculated the pressure difference for flight will be approximately 12.56 psi (it will actually be much less due to a much lower expected altitude as of 2/2/2018):
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Given that we plan to use 180lb of shear pins, this provides a minimum of ~11.7 factor of safety on premature separation due to internal pressure buildup.
Another requirement of the piston is that it cannot break the shear pins prematurely due to an internal build-up of pressure caused by the altitude difference. Between 4,245 ft (the altitude of Truth or Consequences, NM) and 152,945 ft ASL (a simulated upper bound on performance as of January 4, 2018), the pressure difference is approximately (given by the 1976 Standard Atmospheric Calculator using no temperature offset) -86600 Pa. Thus, the following graph of maximum piston area based on the amount of shear pins used can be estimated:
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Resources:
The following resources are useful materials for learning about pressure vessel and piston theory:
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Note that this standard was cancelled in July, 2002.
[4] Aerospace Corporation, Operational Guidelines for Spaceflight Pressure Vessels
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