PROJECT ENDED. This repository contains the archived data for CCC Basel's "Matemat" vending machine project. Use at your own risk. https://wiki.ccc-basel.ch/index.php/Matemat
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matemat.lib Added optional linear regulator for 5V Vcc. 2015-12-30 12:24:08 +01:00
matemat.mod Updated PCB 2015-04-06 14:13:22 +02:00
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README.md Updated CAN interface docs 2021-01-17 15:38:50 +01:00
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Matemat

The Matemat is a vending machine for carbonated soft drinks.

It is based on an old vending machine with all its electronics replaced by new custom-build circuit boards.

All hardware and software was designed by members of CCC Basel and released in the form of circuit diagrams, printed circuit board layouts and source code for anyone to use and modify. Refer to the LICENSE file for details.

The name "Matemat" is a portmanteau of "mate" (as in mate tea) and "automat" (the German word for vending machine). The device is mainly intended to dispense mate tea based soft drinks, but may be used for other types of beverages too.

Structure

The heart of the vending machine is a Raspberry Pi model 3 or zero or later, with a custom CAN interface board on its GPIO header.

See CAN Hat for more information.

Firmware

Some of the modules require firmware. There is a makefile in each module's firmware directory to build and flash the firmware to the integrated microcontroller

Before building, you need to check out the CAN driver source code, which is referenced as a Git submodule.

Run the following commands in the checked out repository:

git submodule init
git submodule update

Modules

The Matemat components are highly modular. Individual circuits are connected by CAN bus, and can be extended as needed.

drive

Single-motor driver.

Attached directly to each bottle release mechanism. Requires only power supply wires for the motor and the CAN bus line.

power

Motor driver board and power supply.

Alternative to the drive board. Uses the existing machine wiring instead of power + CAN.

control

Old central control board. Obsolete.

feedback

End switch feedback interface.

Senses the status of the end switches and sends CAN bus messages on changes.

This module requires firmware. Connect an Atmel programmer to the ISP header, change into the firmware directory feedback/firmware/ and run:

make flash

poweriface

Interface between CAN bus and power board.

This module requires firmware. Connect an Atmel programmer to the ISP header, change into the firmware directory poweriface/firmware/ and run:

make flash

sensor

Environment sensor interface.

wiring

Wring schema of the old vending machine.

Bus

Topology

All modules are connected via a CAN bus. It is highly recommended to wire them by means of shielded twisted-pair cable with a nominal impedance of 120Ω. At the very least, you need a cable with three wires to ensure a good ground connection between all modules.

To allow for easy wiring, six-pole screw terminals are mounted to the PCBs. Two poles are intended for the positive CAN bus line, two for the negative line and two for the shield. They are internally connected together.

Wiring

To achieve a continuous bus topology, connect only two cables to each module. Make sure CAN H is connected to CAN H and CAN L to CAN L. Crossover is not supported on the CAN bus. When wiring is complete, you should end up with a continuous bus that is tapped at each module. Attach 120Ω resistors (preferably 1% or better) to the ends of the bus.

The final wiring should look like this:

┌───────────┐   ┌───────────┐   ┌───────────┐
│  module1  │   │  module2  │   │  module3  │
│           │   │           │   │           │
│H L ⏚ H L ⏚│   │H L ⏚ H L ⏚│   │H L ⏚ H L ⏚│
└╥─╥─╥─╥─╥─╥┘   └╥─╥─╥─╥─╥─╥┘   └╥─╥─╥─╥─╥─╥┘
 ╰━╯   └╥┘╱      └╥┘╱  └╥┘╱      └╥┘╱  ╰━╯
 120Ω   ║╱        ║╱    ║╱        ║╱   120Ω
        ╚═════════╝     ╚═════════╝

Protocol

Bus communication only makes use of basic CAN features. No higher-level protocols such as CiA, EtherCAN, VSCP or similar are required.

Normal 11-bit CAN adressing mode is used.

This is the list of supported message IDs:

Message ID Sender Receiver RTR Support? Data Length Data Format Description
0x10 feedback any yes 2 0b00000KJI 0bHGFEDCBA Feedback module status report (A..E = end switch D..H, F..J = empty switch D..H, K = reset switch, 0 = off, 1 = on)
0x11 poweriface any yes 2 0bHHHHHHHH 0bLLLLLLLL Power module status report (0xHHLL are the contents of the 16-bit shift register)
0x21 controller poweriface no 1 0b00000MMM Start dispensing from slot M (0-4)