Rainwater

2011-03-06T18:43:06Z

Chully: /* Links */

{{Category=Water}}

==Introduction==
[[wikipedia:Rainwater harvesting|Harvesting rainwater]] is generally the easiest way ensuring a clean water supply. Rainwater is usually very clean, and, unlike well water or mains water, there is no need to use energy to pump it long distances. Mike Reynolods, the inventor of [[Earthships]], has said that a house with water-efficient fittings such as a [[greywater]] system can be self-sufficient using just rain water provided the annual rainfall is over 8 inches (20cm).

There are a number of [[Water filters|options for filtering]] rainwater before use.

==Links==
* http://www.climate-charts.com/World-Climate-Maps.html#rain World Map Annual Rainfall
* http://www.harvesth2o.com/ - The Online Rainwater Harvesting Community
* http://www.harvestingrainwater.com/rainwater-harvesting-inforesources/
* http://rainwater.sustainablesources.com/
* [[appropedia: Portal:Rainwater harvesting]]

Open Source Stepper Motor Controller

2011-02-19T14:46:44Z

Chully: /* References */

=Introduction=

Stepper motors are the simplest drive for moderate precision motion control applications (such as CNC plasma cutting). They provide the best price:performace for low to moderate mechanical power (<200W) at low to moderate RPM (<500 RPM). There is no open source stepper driver, AFAIK. This project will fill that need.

=Concept=

The output of this project will be a family of general purpose electronic drivers for a variety of electromechanical actuators. The first of them will be a stepper motor driver. With the appropriate alternative firmware (embedded software) the same hardware might be used as a servo driver for a brush-DC servo. With a modified output stage we could drive brushless DC or AC servos, or linear motors.

=Design Rationale=

Adaptability is good. Software is usually easier than hardware. Microprocessors are cheap. Simple circuits are better than complicated ones (other things being equal).

We keep the circuit simple and general, and we implement the control algorithm in software. We can tweak it most easily that way, and even replace it with something totally different.

This design should give good performance, excellent versatility, good replicability, and moderate cost.

=Block Diagram and Modules=

Major functional units:
* Computational logic. An Arduino could be used in the initial prototype, for speed of development. Later versions would want a cost reduced and/or higher performance microprocessor, or an FPGA for minimum latency and maximum bandwidth. The logic must be shielded from electromagnetic interference by the other parts of the system, especially the output drive (and the plasma cutter, if there is one). Independent power and small signal power supplies, and careful grounding, are likely to be needed.
* Fast A/D converters. Allows the logic to monitor the current flowing through the load.
* High power robust drive circuit. N-channel power MOSFETs in an H bridge, with appropriate protection. Select MOSFETs with plenty of current and voltage headroom, and favour ones with built in clamp diodes. A stepper motor is a heavily inductive load, so it can generate voltages substantially outside the supply rails.

[[File:Stepper-drive-block-diagram.jpg|200px|Stepper drive block diagram.]]

[[File:Stepper-drive-H-bridge.jpg|200px|Stepper drive H-bridge.]]

An H-bridge allows the voltage to be applied to the load (to motor winding) in either direction.

[[File:Stepper-drive-schematic-symbols.jpg|200px|Stepper drive schematic symbols.]]

[[File:Stepper-drive-normal-operation.jpg|200px|Stepper drive normal operation.]]

Top row: active current path. Bottom row: Corresponding Current (I) and Voltage (V) graphed against time.

From left to right: Positive applied voltage, rapidly increasing current; No voltage (except due to the resistance of the wires, gradually decreasing current; Negative applied voltage, rapidly falling current.

[[File:Stepper-drive-failure-modes.jpg|200px|Stepper drive failure modes.]]

Shoot-through occurs when both transistors on one side of the H are turned on at the same time. It shorts the rails together and blows the transistors in a few us.

The overvoltage shown occurs when all the transistors are turned off simultaneously while current is flowing. Stopping the current near instantly creates a huge voltage spike. The same effect can occur if a motor lead comes loose while the driver is operating.

[[File:Stepper-drive-waveforms.jpg|200px|Stepper drive waveforms.]]

Contrast stepping with microstepping. The microstepping gives less vibration and smoother movement, and makes it possible to stop between the steps.

[[File:Stepper-drive-MOSFET-timing.jpg|200px|Stepper drive MOSFET timing.]]

MOSFETS take some time to turn on and off. We need to take account of this for optimum performance (or even for to avoid the above failure modes?). See the MOSFET data sheet for exact timings.

=== Method of operation: ===

*Position instructions come to the drive from EMC. These could be step and direction pulses or some more structured data.
*The drive determines target current for each winding.
*The drive uses software [http://en.wikipedia.org/wiki/PID_controller PID] compensation to achieve and maintain those drive currents.
** sensor: voltage induced across sense resistor by the drive current.
** actuator: [http://en.wikipedia.org/wiki/Pulse-width_modulation PWM] of applied voltage between the three normal operation modes.
*The drive determines new target current for next (micro-)step.

=Prior Art=

This design offers a higher power version (up to 75 amps) of a stepper motor controller, and addresses the feedback loop:

http://www.piclist.com/techref/io/stepper/hipwrbp-gm.htm

[[Image:steppermotorcontroller.gif]]

==Comment by Chris Palmer==
That is only part of a driver circuit. The current sense circuit is not shown and it looks like the firmware will have to do the sequencing, current control and microstepping. The LM5101 is not recommended for new designs.

There are more modern chips that you just add external FETs and sense resistors to get a complete microstepping chopper driver. For example: http://www.allegromicro.com/en/Products/Part_Numbers/3986/index.asp

=References=
*[http://en.wikipedia.org/wiki/Stepper_motor Stepper Motor in Wikipedia]
*[http://www.cs.uiowa.edu/~jones/step/index.html An excellent discussion of concepts]

=Development Team=

[[Leo.dearden]] - Ideas. I'm too busy to do very much at the moment, but I'll do what I can.

[[Category:RepLab]][[Category:Automation]]

Talk:Scalability

2011-02-19T05:21:09Z

Chully: Created page with "Sorry to create a new page, but I don't know where better to discuss scalability. Please redirect if necessary. I just wanted to ask: what is the project's stance on a [http://..."

Sorry to create a new page, but I don't know where better to discuss scalability. Please redirect if necessary.

I just wanted to ask: what is the project's stance on a [http://en.wikipedia.org/wiki/Fork_(software_development) fork] of OSE in another location?

Open Source Ecology - User contributions [en]

Rainwater

Open Source Stepper Motor Controller

Talk:Scalability