Twizy-Virtual-BMS/extras/Twizy-Battery-Part-List.md
2017-07-09 12:09:53 +02:00

9.6 KiB

Twizy Battery Part List

For explosion drawings and OE part numbers, see…

  1. partsouq.com
  2. catcar.info

A good source for all parts is JC Parts.

Fuses, connectors and relais

# Image Part OE number ~Price
1x 296539341R Fusible Principal Fltg Ent Chr
Main fuse 500A
296539341R 4.41 €
1x 296539051R Fusible Chargeur Fltg Ent Chrj
Charge fuse 50A
296539051R 1.67 €
1x 296535672R Fusible Apres Contact Fltg Ent
Precharge fuse 5A
296535672R 1.30 €
1x 296535672R Platine Fusible
Main fuse holder
296535672R 10.48 €
1x 296712452R Platine Fusible
Charge fuse holder
296712452R 7.96 €
1x 296743399R Embase Connecteur Batterie Tra
Main connector (DELPHI)
296743399R 52.22 €
1x 296746418R Embase Connecteur Ba
Charge connector (DELPHI)
296746418R 30.67 €
1x 296740718R Embase Connecteur
Signal connector (Yazaki)
296740718R 86.30 €
1x 294B16331R Relais Principal Boitier Cnx P
Main relais 150A
294B16331R 56.63 €
1x 294B20431R Relais Precharge Boitier Cnx P
Precharge relais 10A
294B20431R 21.19 €
1x 296156226R Relais Chargeur Fltg Ent Chrjr
Charge relais 40A
296156226R 39.96 €
Total (prices may change) ~ 310 €

Parts may of course be replaced by functionally compatible ones, for example use a fork lift relais for the main power relais (relais & fuses are no special parts). Błażej Błaszczyk has built his prototype without using Renault parts. For details please contact him at blazej.blaszczyk@pascal-engineering.com.

  • The 296740718R signal connector is Yazaki part no. 7282-8854-30 (contact terminals sold separate).
  • The 296743399R main power connector is DELPHI part no. F473110, with contact terminals F176600.
  • The 296746418R charger power connector is DELPHI part no. F873110, with contact terminals 15516298.

Casing

# Image Part OE number ~Price
1x 295F00162R CARTER SUP BATTERI
Casing cover
295F00162R 129 €
1x 295F19016R CARTER INF BATTERI
Casing base
295F19016R 216 €
1x JOINT ETC CARTER B
Casing seal
295G32560R 46 €
Total (prices may change) ~ 390 €

Note: Lutz Schäfer offers to build individual custom battery cases offering more space. For details please contact him at aquillo@t-online.de.

Sizes:

  • Standard Renault Box: 724 x 368 x 208 mm
  • Lutz-Box V1 (without car modification): 745 x 400 x 245 mm
  • Lutz-Box V2 (car modification necessary): 745 x 480 x 245 mm

Arduino

Note: if you plan to use Pascals integrated Twizy BMS, you won't need an Arduino. The integrated BMS also implements the Twizy protocol.

For a basic setup you'll need an Arduino, a CAN interface and a relais to switch the 3MW signal.

If you want/need to measure cell voltages and temperatures with the Arduino, you will most probably need some analog input extension. A very simple and cheap setup for up to 16 cells is to use an analog multiplexer based on the CD74HC4067 chip.

Standard Arduinos can be powered from 12V, but will burn the voltage difference (convert to heat), so a step-down voltage regulator is highly recommended. The Pololu A-Star SV series has on-board step-down regulators suitable for a 12V supply.

Using an Arduino Uno style main board with shields reduces soldering requirements but needs more money and space than for example a Nano based board with break out components.

Keep in mind for all setups, this is an automotive application: expect high levels of mechanical stress due to road shocks and temperature expansion/contraction. Protect your electronics against humidity.

Price note: there are lots of cheap Arduino clones available. These can of course be used as well. Expect a lower build quality, so better order some spares (always a good idea).

Example basic Uno/Shield setup

Category Component ~Price
Main+Power Pololu A-Star 32U4 Prime SV 24.95 €
CAN Seeed Studio CAN-BUS Shield v1.2 24.95 €
Relais Seeed Studio Relais Shield V3.0 21.95 €
Total ~ 72 €

Example basic Nano setup

Category Component ~Price
Main Arduino Nano V3 clone 4.95 €
I/O Arduino NANO Screw Terminal Expansion Board 4.95 €
CAN NiRen MCP2515_CAN (TJA1050) 4.50 €
CAN … 16 MHz quartz 0.23 €
Relais 5V 2 Channel Relay Shield 2.95 €
Total ~ 18 €

Example components

Category Component ~Price
Main Arduino Uno R3 20.80 €
Main Arduino Nano V3 23.80 €
Main+Power Pololu A-Star 32U4 Prime SV 24.95 €
Power Pololu 5V, 2.5A Step-Down Voltage Regulator D24V22F5 8.95 €
CAN Seeed Studio CAN-BUS Shield v1.2 24.95 €
CAN NiRen MCP2515_CAN (TJA1050)
Note: these come with 8 MHz quartz, you should replace this with a 16 MHz type
4.50 €
Relais Seeed Studio Relais Shield V3.0 21.95 €
Relais 5V 2 Channel Relay Shield 2.95 €
I/O Adafruit Proto-Screwshield 15.50 €
I/O Arduino NANO Screw Terminal Expansion Board 4.95 €
I/O SparkFun Analog/Digital MUX Breakout - CD74HC4067 (16 Channel) 4.95 €
I/O Adafruit ADS1015 12-Bit ADC - 4 Channel 10.95 €
I/O Mayhew Labs Extended ADC Shield 30 €
I/O Seeed Studio RS232 Shield 12.50 €
I/O HC-05 Bluetooth module 6.00 €

Example Arduino wiring scheme

This example setup could be used for a battery pack with a very basic BMS that does only cell protection and has no communication interface. So the Arduino is used to monitor cell voltages, pack current and temperature. This is all optional -- basically you could derive the SOC estimation from just the overall pack voltage as well.

Arduino Example Wiring

The Fritzing diagram only shows the I/O connections, but there's little more: add power supply and enable the multiplexer permanently (connect pin EN to VCC). Obviously, when using a CAN shield like shown in the diagram, it's wiring is done by mounting the shield.

The bluetooth module is optional but neat, it enables to check your VirtualBMS output with a smartphone.

Cell voltages can be measured using the multiplexer shown and simple voltage dividers measuring the stacked voltages, but keep in mind you lose precision by the scaling. The Arduino analog ports provide 10 bit resolution on the voltage range of 0-5 V = ~5 mV. So when scaling to 60 V, resolution drops to ~60 mV. This is good enough to detect a bad cell, but not for precise health monitoring. You may use ADC shields with higher resolution and/or differential voltage probes to get the single cell voltages, but when thinking about this, take a look at specialized battery monitoring chips like the MAX11080 or LTC6811 first.

The pack current can be measured using either a shunt (with an instrumentation amplifier or an ADC with preamp) or a hall sensor module like the LEM HAC 600-S. The LEM outputs -4…+4 V so needs to be mapped to the Arduino's 0…5 V (i.e. using a voltage divider).

The temperatures can be measured using LM35 sensors. Depending on the variant used, voltage may need to be mapped to the Arduino input. If you want to measure every single cell temperature, you can also extend the setup by another MUX for the temperature sensors -- just use the same address pins as for the voltage MUX.