Assembling the RapMan V3.1 3D printer: Difference between revisions

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This article has two functions:
This article has two functions:
* It's a '''meta manual''' for '''Rapman version 3.1''': We will try to explain how RapMan works in order to help the reader understanding stages of assembly and we will point out the most important manuals and other information sources you should read
* It's a '''meta manual''' for assemblying the [[Rapman]] version 3.1 3D printer: We will try to explain how RapMan works in order to help the reader understanding stages of assembly and we will point out the most important manuals and other information sources you should read
* We will add some missing points and report some difficulties (and solutions).
* We will add some missing points and report some difficulties (and solutions).



Revision as of 12:32, 9 April 2010

Introduction

This article has two functions:

  • It's a meta manual for assemblying the Rapman version 3.1 3D printer: We will try to explain how RapMan works in order to help the reader understanding stages of assembly and we will point out the most important manuals and other information sources you should read
  • We will add some missing points and report some difficulties (and solutions).

Parts, manuals and workspace

Boxes from RapMan delivered on Jan 2010
Bad base bed hole in the Rapman kit
The workspace

When we ordered a RepRap it came in a fairly small plastic-wrapped cardboard box. In addition, we got some boxes with polymer filaments (10 ABS rolls and 4 PLA rolls). To the left is a picture.

You may check the insides of the boxes. E.g. compare contents to the list that you can find in each of the three following manuals, i.e. in the "included" section in the beginning.

  1. Build manual (for the "cartesian robot")
  2. Extruder manual
  3. Hot End manual (pink cables were missing from both the 3.1 version and in our case in the delivered kit)

Finally, there may be faulty pieces. In our case the holes in the base bed (page 51 of the build manual) were not straight. Other folks in the forum reported this problem. IMHO ours were sort of straight enough. The setup, i.e. a bolt with a spring that ties down the print bed is used to micro-adjust the level of the print bed in 3 dimensions (see the operations manual).

Assembly is easier if you can reserve a lot of space for assembly. At TECFA, we used our seminar room and took about 2 x 6 meters :). See picture to the right.

The result

Keep the following picture from the build manual in mind. This is what you are going to build. The most important parts are labeled (we added the hot end, i.e. part of the extruder that will heat the plastic filament).

Rapman 3.1. schema - Source: bits from Bytes, build manual 3.1 - printed (reproduced without permission)

You also should look a real picture, below is ours:

Rapman 3.1. assembled at TECFA (just after assembly)

Overview of the manuals

All manuals are available at Bits from Bytes. At the time of writing (feb 2010) they could be found in the downloads section. The "build info" section includes outdated version. So, in any case, always make sure that you get the manuals for the version you ordered, e.g. RapMan 3.1. Here is a list of the manuals:

  • Build Manual - Printed: This manual explains how to assemble the so-called cartesian robot. This refers to the printer (including the motors and the belts that will move the extruder in the X/Y axis and the plate up/down (Z-axis). In other words, it's all that's mechanical, except the extruder.
  • 3D Build Manual part 1: As above but include 3D models that you can view in PDF. Click on a "picture" to enter 3D mode. Make sure to install the latest PDF version and to use a PC with a decent graphics card. Also, explore the Acrobat menu to the left. You can add-remove parts for better visibility.
  • 3D Build Manual Part 2: As above, part 2. Also includes writing of the motors and the controller.
  • Animated Build Manual: As above, but includes animations. We didn't use this manual.
  • Build Manual Videos: This manual includes three videos that show how to build some of the more difficult parts.
  • Extruder Manual: Explains how to assemble the extruder, i.e. the print head that will be moved around in X/Y directions by the "cartesian robot". It will pull in the plastic filament and feed it into the so-called attached hot end which you somewhere during the assembly process. Finally it also explains how to wire the extruder to the controller.
  • Hot End Manual: Explains how to assemble the hot end. The hot end will heat the plastic. It's a bit tricky to assemble, since you have to wrap a heating wire around, attach a temperature probe and cover with fire cement in several stages.
  • Operations Manual: Explains how to calibrate and use the printer. In particular: calibrate the print head, update the firmware, use the controller interface and print files.

Notice: In some case, the newer manual versions did not have enough information to understand the process. We had to look at some 3.0 version manuals where procedures are explained in more detail. However, this information needed to be adapted, because some parts are not the same and generally speaking 3.1 is easier, in particular assembling the hot end !

As of Feb 2010, the build manual is quite superb (with little mistakes), the Extruder manual is ok enough, since at this stage you can build without reading .... The Hot end manual is not good enough (yet).

Tools

You will need tools. All except two can be easily found in a do-it-yourself store. Read: V3Info.pdf (this file may not sit next to the build manual). Dictionary (terms are in UK English):

  • A spanner is called Wrench in US English, "clef à écrous" en français
  • Allen key is a "hex key" or "hex head wrench"
  • A Needle file is a small abrasive file, the kind modeling hobbyists would use.

(1) Easy to find tools:

  • 4mm Spanner 1
  • 5.5mm Spanner 1
  • 8mm Spanner 1
  • 13mm Spanner 2
  • 1.5mm Ball End Allen Key 1 (it's important to get ball ended keys, since sometimes you will "come in diagonally". We suggest to buy quality tools, because of easier fit).
  • 2.5mm Ball End Allen Key 1
  • 4mm Ball End Allen Key 1
  • 2mm Flat Blade Screw Driver 1 (get a good one, this is need for attaching wires to the board)
  • Tape Measure 1
  • Soldering Iron 1
  • 1/2 Round Needle File 1 (we actually suggest to buy several ones including a square-shaped one. Since these are used by modeling fans you can get handful of various shapes for about 5 to 15 Euros (depending on quality). We got the cheap ones.
  • Wire Cutters 1 (maybe not needed, since a stripper also can cut)
  • Wire Strippers

(2) Difficult to find tools:

  • A good multimeter that can measure small resistance. Not difficult to find actually, but may not be found in a supermarket. We didn't test resistances as we should have ... ;)
  • A 1/16'' Allen key. We found it w/o problem in a hardware store that sells to professionals.

(3) Extra tools (not mentioned in the bills of tools)

  • You might acquire a key that can measure a small torque pressure (the typical thing you get in a do-it-yourself shop is just good for the nuts on car wheels). This is an expensive professional tool. We didn't get one. (see practice run)
  • At least two Pliers. One should be long and flat. Useful for holding nuts in place before you use the keys. Cheap ones will do.
  • A small (!) tube of super glue. I broke the extruder wheel (the only thing we broke) and fixed it with super glue :)
  • A hammer. You are allowed to use it only once though :(
  • Various meters, i.e. a long flat 2 meters one for measuring cables and a small metal one (preferably one whose end starts at zero, else a plastic office-type one can also do). The latter one is to measure distances in the assembly and for selecting bolts.
  • A (no bigger than 2GB) standard SD card. It will be inserted into the board to print files.

The assembly procedure

Practice run and parts terminology

The practice run has three important functions:

(1) You will learn how much you can tighten the screws. The golden rule is simple: really finger tight then add 1/2 turn with a key.

(2) Terminology: Although we do understand English, we didn't know about these:

  • A washer is a "flat disk" (rondelle in french)

Also remember to look at the "big picture" on top for terminology of the rapman parts.

(3) Learn how to read the manual. You quickly will learn about the names of nuts and bolts:

The cartesian robot

The cartesian robot is fairly easy to build if you understand English and are used to reading computer manuals for example. It takes about 2-3 full days (2 persons working on it).

Things that will go wrong:

  • Some pieces may be assembled in a wrong way. Make sure to pay attention to "asymmetric" pieces.
  • Again: Do not over-tighten. Plexiglass can shatter quickly.
  • Geometry. If you do it right, most everything should be "cubic", i.e. same distances and 90 degree angles. If you get that wrong, the printer will not work properly. Make sure to do the calibration rights (as explained in the build manuals).

Sometimes you need to inserts bolts in the plexiglass parts. If you can't insert these, don't force too much, but use a needle file to clean the aperture or even to enlarge it. This is why we recommend to get a whole set of small needle files in various shapes.

The extruder and hot end

The extruder and the hot end are described in different manuals plus in the videos PDF.

The Extruder manual explains how to assemble the mechanical parts of the Extruder. This part is fairly easy.

The hot end manual is not clear enough:

  • The manual includes instructions for two different versions of the kit, i.e. insulated vs. non-insulated nichrome. Nichrome is a resistance wire that will heat. It's the kind of wire you may find in a toaster.
  • The parts you get are not the same as the ones described in the manual. E.g. the kit already included a non-isolated nichrome wire with the bootlace ferrules attached (i.e. step 9 on page 5 already was completed in the kit I got).
Hot end + some other intriguing parts

The nozzle assembly (part one) is easy. The tricky part is wrapping the nichrome, fire cementing it, adding the thermistor and fire cementing again.

Here is what we did:

  • Attach the nichrome to cables (as explained). You have to attach wires with the ferrules and squeeze these with a plier, then slide the yellow head-proof sleeves over it (in the manual, explained before nozzle assemble)
  • Put a small layer of fire cement around the aluminum nozzle
  • Make sure that the wires will be on the side of the hole of the MDF !
  • Wrap the nichrome around (make sure they don't touch)
  • Add fire cement. Be careful not to smear anything inside the nozzle hole or the thermistor hole), then wait 12h.
  • Add the thermistor (this is a bit tricky since you'll have to add fire cement again).
  • Then cook with the ventilator outlets (as explained in the manual)
  • Then add more fire cement to make it look pretty. Don't add too much, else you won't be able to slip the insulation around and printing will be slower since the hot end will cool faster.
  • Cook again (actually much longer than they say)

Since we didn't have a good enough multimeter, we didn't test anything after it. If we made it wrong, we'd have to order a new hot end kit anyhow ...

Below is picture of the hot end, printing a giant duck:

Print head (hot end) printing ...

Test printing and tuning

There are three levels of tuning

  1. Make sure that the assembly is compliant with the instructions in the Manual
  2. Get the temperature, flow rate, and head movement speed combinations right
  3. Micro ajustments (geometry, belts, etc. and item 2

Last minute checks and trouble shooting

Check the following (we had all of these wrong in some ways)

(1) Alignment of the X and Y axis

  • Alignment of the X and Y axis is crucial. If badly aligned then a circle may print as ugly sort of square. This happened to us, because we took the Y belts away to check the motor.

(2) Belt tensions

  • Make sure all three are tight

(3) Z belt tension and alignment, wobbling Z rods:

  • Make sure that the end of the rods, i.e. the ball bearings, sit in their casings (rebates). Clean these with a needle file again if necessary. If you don't, the Z axis will be misaligned, rods may wobble, or you hear noisy clicks, because the belt will not be aligned properly.

(4) Extruder

  • That was my huge mistake: I attached the pressure wheels in the wrong way. The side where the wheels stick out should be toward the extruder. Else, the big fat bolt can't move the plastic filament. Big frustration after you try to print the first test pattern :(
  • Make sure that the extruder is nicely attached. At some point I removed the extruder to check the nozzle and forgot to tighten 2 screws. Result was a skewed print, i.e. the yellow cup you can see in a picture.

(5) Attached wires

  • Even if you did attach the wires to the board and the 25 way pin as told, they may become loose. E.g. in our case the red wire for the Y motor became loose on the board and the motor would just crank a little bit forward and backward. We thought that it would be a too tight Y Drive shaft, disassembled this one and then wound up with misaligned Y belts, i.e. the the X carriage wasn't aligned anymore with the Y(0) end...

(6) Search for loose nuts and bolts (also after printing a few test objects)

(7) SD card memory errors: Format the card before you use it. You may have to repeat this if errors pop up again.

Hardware calibration

Rough alignment of the print bed:

  • Align the bed horizontally with respect to the Z axis. I.e. remove the Z belt and turn the rods
  • Keep the print head at a safe distance, e.g. 0.5 cm and move it around manually. Then go closer until you are more or less satisfied.

Copy the Control Interface page of the operation manual and over-line the important manual move mode commands, i.e. you should keep this page near the control until you know commands by heart.

Then, power up, and move the print head around in all three axis. If a motor won't work, check wirings. If you hear strange noises, check alignments and belt tension.

Fine tuning of the print bed alignment

Adjust the print bed with bolts. This is a bit tricky and needs several iterations. In each position, the nozzle should be about 0.5 mm away from the print bed. We used five sheets of 70mg paper (500 sheets = 5cm) to do this.

Go slowly when you move the print head. Don't damage the board !

The coordinate system:

The 0/0 coordinates are in the center.

  • X goes from -135 to 140
  • Y goes from -100 to 105
  • Z goes from 0 to 230

How does Rapman know where the print head is ?

  • Look at the coordinates in the manual setup. If the print head is in the center and the X/Y coordinates are different, then something is wrong.
  • Move it to the center and turn rapman off. Then home it and turn it off again. This is particularly important if you make a change the Z axis, e.g. move the board up or down by a 1/10 of a millimetre. Change, then turn it off.

Inserting the filament and manual extruding

Make sure that you rough up the print bed with sand paper. Remove the dust, e.g. you can easily remove the print bed, sand it, then wash it. The principle is that the filament has to stick.

The nozzle, when cold, takes some time to heat. Don't worry if nothing happens during a few minutes. At some point you will see the temperature going up. Also you should know, that temperature drops pretty fast which is a problem with the test files. E.g. if you print without manually extruding some plastic beforehand, things go wrong.

Use manual mode, i.e. Tool setup

  1. Put the print head in position over the hole (front side, right)
  2. Up the temperature to 245-250 degrees: Press +/- Y
  3. Up the extrusion rate to 5mm/s(econd) = 10 RPM: Press +/- X

Then, as soon as the bolt in the extruder starts turning (temperature reached):

  1. Push in the filament (really down)
  2. Tighten the two screws (red caps)
  3. Paint a dot on the filament to check if it goes down ... If it does not, then tighten. If the motor blocks or if it jumps, loosen
  4. Print at least half a meter

Then, as quickly as you can, run a print file (see below)

Changing the filament

Before you can insert new plastic:

  • Heat up the nozzle
  • Pull out the old filament
  • Push in the new one
  • Extrude manually until the color changes ...

Insert the filament as explained above

Printing the test pattern

Don't panic, the second print should be much better

(1) Upgrade the firmware as explained in the operations manual. To do so you need:

  • A small to normal USB cable
  • The HIDBootLoader.exe application
  • The firmware, e.g. file RapMan2_0_8.hex (as of Feb 2010)

(2) Then print the test raft pattern.

  • Copy file 'TestRa.bfb to the SD card
  • Insert in the board and print ...

(3) Repair the TestRa.bfb file to make it fit your situation. Most likely temperatures are too low (see G-code below). Your first print will go miserably wrong, unless you are either very good or very lucky.

You also may ajust the belts and other geometry. Our very first cup (see aside) went horrible wrong since we took off a Y belt and the forget to re-adjust as we already explained.