字幕列表 影片播放 列印英文字幕 Hi my name is Massimo Banzi and I like to make stuff. Welcome to another Arduino tutorial video. Today we are going to learn how to use Arduino to move things in the real world. To do that, we need to learn how to control a DC motor using Arduino. The DC motor is a simple electro-mechanical device that you can see here. It is normally powered by a 9V battery We are going to build a circuit that will let Arduino turn on and off this motor. And we will be using that to control this colour wheel that we have manufactured using an old CD. In the kit, you will find parts in order to build the wheel adapter, and you will find the paper that you can glue on top of the CD. There are some issues that we have to take care of. First of all the DC motor here works normally at more than 5V, which is the standard voltage that Arduino operates at, and it requires more current than a single Arduino pin can provide. Normally, we can just hook up a regular LED to an Arduino pin, because the amount of electrical current that the LED needs in order to operate is low enough that you can power it with an Arduino pin. But in the case of the DC motor, the motor requires a current which is much higher, and we risk burning the Arduino pin if we try to hook it up directly. There is also another issue that we have to be aware of: when you turn on and off an electric motor - when you turn it off actually - it generates a spike of negative voltage that can actually go back into your equipment and destroy some of the parts. In order to solve this problem we are going to use a new component that we haven't used in the other videos, which is called 'mosfet transistor' This is essentially a switch that can be turned on and off by applying - or not - a voltage to a certain pin of the mosfet transistor. The mosfet here has 3 pins called source, drain, and gate. The mosfet is essentially an electronic switch that can be turned on or off by applying a voltage on a pin called 'gate'. So this mosfet transistor has 3 pins called gate, source and drain. If you apply a voltage to the gate pin it connects the gate and the source together, as if I was pressing a button on a switch, but this is all done electronically. So I can use this to connect the battery to the motor, and since the mosfet is sitting in-between it basically connects and disconnects the motor from the battery and I can control this through software that I write on the Arduino board. When you turn off an electric motor, it normally generates a spike of negative voltage that can destroy your equipment. Even if the mosfet is quite strong it is still very sensitive to these negatives spikes of voltage, so we have added to the circuit this "flywheel diode" that conducts only when the motor generates these dangerous spikes of voltage and protects the mosfet from burning. So what the mosfet is doing for us: it lets us control loads that are larger than we can normally manage with an Arduino pin; it lets us operate at a voltage, which is higher than the standard Arduino voltage. As I said, Arduino operates at 5V but the battery here is 9V. Using the mosfet allows us to switch on and off bigger loads that operate at voltages that are higher than the Arduino standard operating voltage. It protects us, because if something happens, the mosfet blows up at worst, but using the diode the way we hooked it up here we can protect the mosfet and we have a fairly reliable and robust way to turn on and off, but even change the speed, if we want, of this DC motor. So let's look at how we can build this circuit. First of all we place the mosfet on the breadboard and then we connect the negative ,the black wire, of the motor right in the middle pin. Then if you look at the mosfet from the front, where you can see the markings, the pin on the left hand side is the 'gate'. We are going to wire it up to pin number 9 on your Arduino. The pin on the right hand side, that's the ground. We are going to connect it with the jumper wire to the ground rail here on the breadboard. Then we are going to connect the ground from the battery together with the ground on the breadboard so that the battery and the Arduino have the ground in common. This is a condition needed so that the power supply on the Arduino and the battery have the ground in common so that the voltages are all referring to the same ground and the circuit can operate properly. So the circuit works like this. We connect the 9v coming from the battery directly to the motor and then from the motor we connect the ground pin of the motor to the mosfet and then the mosfet connects to the actual ground on the circuit. So when the Arduino pin turns on and off, a 5v voltage will be applied to the gate. When the gate receives the voltage from the Arduino pin, it will connect the motor to ground and the motor will start to spin. When we remove the voltage from the gate pin, the mosfet will open and the circuit will break and the motor will stop running. Let's look at the sensor part of the circuit. In our case the sensor is a button, so we wire up the circuit in the usual way. We have a button here. We have the resistor, which is a pull-down resistor, so we connect power to the button, button to resistor, resistor to ground, and the point where the button and the resistor connect, that's where we connect the wire to take that voltage and bring it to pin 2 on the Arduino. Every time I press the button, the Arduino detects that condition and turns on the mosfet. Here we have a motor and here is a small adapter which adapts the motor shaft to this pinwheel that we manufactured using al old CD and a piece of paper that you can find in the kit. Once I created the adapter, I am going to put a little bit of glue on it, so that the cd is not going to fly away the moment I turn on the motor. Let's put a few drops of glue. Let's try. You can see now that it is picking up speed and it's turning into this interesting cappuccino colour. If I release the button the motor starts to slow down. That's pretty good. So this was our example and now let's have a look at the code. Starting from the beginning we have a couple of constants. switchPin, that maps the switch to pin number 2, and motorPin that maps the motor on pin 9 Then we have a variable called switchState = 0; which will contain the state of the push-button and it will be used in an if-statement to determine if the motor has to be on or off. Then let's look at the setup() There is a pinMode(motorPin, OUTPUT); that defines that the pin that connects to the mosfet and controls the motor is an output. And pinMode(switchPin, INPUT) that basically says that the pin connecting to the pushbutton is an input. Then let's now look at the main loop. Inside the loop we begin by reading the state of the button by saying switchState = digitalRead(switchPin); This reads the current state of the button and then places HIGH or LOW values inside the switchState variable. After that we have an if-statement. If (switchState == HIGH), so if the button is pressed, digitalWrite(motorPin, HIGH); which turns on the motor. else digitalWrite(motorPin, LOW); This if-statement looks at the state of the button and if the button is pressed we turn on the pin, if the button is released, we turn off the pin. When the pin is on, the mosfet connects and it starts the motor. This is all the code that is needed to build this simple application. Now you can hack the software and add more functionality. For example if you look online, you may be able to find some code that teaches you how to turn on the motor when you press once, or if you press again it turns it off, or to operate a toggle switch, or you can learn how to change the speed of the motor. So the number of things you can do now with this project are a lot. Remember: build it, hack it and share it, because Arduino is you!
B1 中級 Arduino視頻教程06:電動風車--------。 (Arduino Video Tutorial 06: Motorized Pinwheel) 116 4 Chuan Zhe Lin 發佈於 2021 年 01 月 14 日 更多分享 分享 收藏 回報 影片單字