I started with the Ship Computer last October but had to stop working on it for a couple of months and hoped to start over again in January.
Which, unfortunately I didn't.
The same time I am setting up a trip around Ionian for which I am planning to get going by mid May, that is, less than 2 and a half months away, and I have to prepare the boat and everything.
Which means that probably there won't be much time for software development...
Nevertheless, I absolutely need some of the functionality the ship computer was going to give me, and knowing that probably I won't have the Ship Computer ready for this trip, I started thinking of alternatives.
One thing that I have to have is a battery monitor.
On the boat I have a 120W solar panel for charging a 65AH battery and, if absolutely necessary, I can also use the outboard alternator for additional 60W of battery charging power. As far as consumption goes, I have installed led-based navigation and cabin lights so that will keep the consumption down. Other source of power consumption include the instruments and the autohelm, for which I am particularly worried.
Anyway, since I only carry a single battery, I need to know how much consumption is there, what is the charging current when applicable and the battery voltage.
In order to get this functionality, I used an arduino Pro Mini, a current sensor (similar to this), a voltage divider set up with two resistors and a 16x2 LCD screen connected to I2C.
For powering I used a low cost 6V UBEC like this one: http://r.ebay.com/NQZ0ne
The finished project looks like this:
In this picture:
- #1 is the current sensor
- #2 if the arduino Pro Mini
- #3 is the insulation for the arduino
- #4 is the UBEC with the insulattion sleeve in place
- #5 is the 16x2 LCD screen
#include <Wire.h>
#include <LiquidCrystal_I2C.h>
float amperes=0;
float volts=0;
LiquidCrystal_I2C lcd(0x27, 2, 1, 0, 4, 5, 6, 7, 3, POSITIVE);
void setup()
{
// initialize the lcd
lcd.begin(16,2);
lcd.clear();
lcd.print("Amps=");
lcd.setCursor ( 0, 1 );
lcd.print("Volts=");
}
void clearValues(){
lcd.setCursor ( 6, 0 );
lcd.print(" ");
lcd.setCursor ( 7, 1 );
lcd.print(" ");
}
void showValues(float Amps,float Volts){
clearValues();
lcd.setCursor ( 6, 0 );
lcd.print(Amps,3);
lcd.setCursor ( 7, 1 );
lcd.print(Volts);
}
void loop()
{
// MEASURE CURRENT
// ampere sensor connected to A3
amperes=0;
long temp=0;
//150 reads, 15 usec delay = total 2.25msec
for(int i = 0; i < 150; i++) {
temp+=analogRead(A7);
amperes = amperes + (.0264 * analogRead(A3) -13.51) / 150;
//function calibrated for 5A sensor
delayMicroseconds(15); //15 usec delay for the A2D to "reset"
}
temp/=150;
amperes=(0.0049*(temp-512))/0.185;
//negative on discharge, positive on charge
amperes*= (-1);
//
// MEASURE VOLTAGE
// voltage divider (1/5) conected at pin A2
temp=0;
//150 reads, 15 usec delay = total 2.25msec delay for a measurement
for(int i = 0; i < 150; i++) {
temp+=analogRead(A3);
delayMicroseconds(15); //15 usec delay for the A2D to "reset"
}
temp/=150; // get the average value
volts=temp*5.01*((19.93+6.8)/6.8)/1024.0; // calculate actual voltage
showValues(amperes,volts);
delay(300);
}
The whole setup is simple, works like a charm and is a way to get some limited but needed functionality even if the Ship Computer is not ready in time for the trip.
That said, I hope to be back soon with a post about the ship computer itself!
Thanks for reading,
G.