FaSTTUBe/scruti-documents
60
0
Fork 0
Code Issues Pull Requests Actions Packages Projects Releases Wiki Activity

Updated TS-DC and SDC-schematic

Browse Source
This commit is contained in:
Hamza Tamim 2025-05-05 20:02:52 +02:00
parent 98d20a9e56
commit f02ea8f51c
5 changed files with 12 additions and 9 deletions

2
README.md

@ -17,7 +17,7 @@ TeX source file for ESF and scrutineering
- [X] Provide latching capability explanation/simulation (AMS and IMD).
- [X] Current consumption
- [X] Describe overcurrent protection
- [ ] TSAL
- [X] TSAL
- [X] Detailed TSAL schematic, including all remote circuitry (DC-link and TSAC output)
- [X] TS Accumulator
- [X] Accumulator TSAL

BIN
SDC-schematic/SDC-schematic.pdf

Binary file not shown.

13
SDC-schematic/SDC-schematic.tex

@ -62,18 +62,21 @@ The current consumption of the components are as follows:
\end{itemize}
\end{multicols}
We can then find the total consumption when we add all the the load together. $\SI{249}{\milli\ampere} \cdot 2 + \SI{8}{\milli\ampere} + \SI{9.6}{\milli\ampere} + \SI{4}{\milli\ampere} \approx \SI{520}{\milli\ampere}$.
We can then find the total consumption when we add all the the load together.
\begin{align}
\SI{249}{\milli\ampere} \cdot 2 + \SI{8}{\milli\ampere} + \SI{9.6}{\milli\ampere} + \SI{4}{\milli\ampere} \approx \SI{520}{\milli\ampere}
\end{align}
\section*{Overcurrent Protection}
See: \hyperlink{./Documents/FT25_PDU-powerstages-SDC (9A).pdf.1}{PDU - SDC} \\
See: \hyperlink{./Documents/FT25_PDU-powerstages-SDC (9A).pdf.1}{PDU - SDC Schematic} \\
The overcurrent protection is achieved with a physical fuse and a power switch on our Power Distribution Unit PCB.
The fuse holder is the 3557-15\cite{fuseholder_datasheet}, which holds our 1A fuse, and the powerswitch is the BTT6050-1ERA\cite{profet_datasheet} from Infineon.
The overcurrent protection is achieved with a physical fuse and a power switch on our Power Distribution Unit (PDU) PCB.
The fuse holder is the 3557-15, which holds our 1A fuse, and the powerswitch is the BTT6050-1ERA from Infineon.\cite{fuseholder_datasheet}\cite{profet_datasheet}
\bibliographystyle{plain}
\includepdf[pages=-, landscape=true, link]{./Documents/SDC.pdf}
\includepdf[pages={9}, landscape=true, link]{./Documents/Master_FT25.pdf}
\includepdf[pages={8}, landscape=true, link]{./Documents/Master_FT25.pdf}
\includepdf[pages=-, landscape=true, link]{./Documents/FT25_PDU-powerstages-SDC (9A).pdf}
\renewcommand\refname{Reference}

BIN
TS-DC-schematic/TS-DC-schematic.pdf

Binary file not shown.

6
TS-DC-schematic/TS-DC-schematic.tex

@ -77,9 +77,9 @@
\section*{Discharge Time}
As seen in the Schematic, for our discharge circuitry a PTC (PTCEL13R251NxE\cite{ptc_datasheet}) is used.
The total capacitance of the DC-link capacitor from the two inverters (Emsiso emDrive H100\cite{emdriver_datasheet}) that we are using is about \SI{200}{\micro\farad},
and the maximum voltage of the accumulator is 403.2V. Using the RC discharging circuit equation, we obtain the highest resistance that the PTC can have so that we are still within the 5s discharge limit.
As seen in the schematic, for our discharge circuitry a PTC (PTCEL13R251NxE) is used.\cite{ptc_datasheet}
The total capacitance of the DC-link capacitor from the two inverters (Emsiso emDrive H100) that we are using is about \SI{200}{\micro\farad},
and the maximum voltage of the accumulator is 403.2V.\cite{emdriver_datasheet} Using the RC discharging circuit equation, we obtain the highest resistance that the PTC can have so that we are still within the 5s discharge limit.
\begin{align}
V_C &= V_0 \cdot e^{-t/RC} \\
\SI{60}{\volt} &= \SI{403.2}{\volt} \cdot e^{-\SI{5}{\second}/(R_{PTC} \cdot \SI{200}{\micro\farad})} \\