• HABITAT: CEB Press - Sawmill - Living Machines - Modular Housing Units
  
• AGROECOLOGY: LifeTrac Multi Purpose Tractor - MicroTrac - Power Cube - Agricultural Spader - Agricultural Microcombine - Hammer Mill - Well Drilling Rig - Organoponic Raised Bed Gardening - Orchard and Nursery - Modular Greenhouse Units - Bakery - Dairy - Energy Food Bars - Freeze Dried Fruit Powders
  
• ENERGY: Pyrolysis Oil - Babington Burner - Solar Combined Heat Power System - Steam Engine Construction Set - Solar Turbine - Electric Motors/Generators - Inverters & Grid Intertie - Batteries
  
• FLEXIBLE INDUSTRY: Lathe - Torch Table - Multimachine & Flex Fab - Plastic Extrusion & Molding - Metal Casting and Extrusion
  
• TRANSPORT: Open Source Car
  
• MATERIALS: Bioplastics

Product Definition

A sawmill enables custom lumber production on site using locally available timber. An easily replicable lumber mill creates real value for the producer at a low cost of entry, a necessity for self sustaining community decentralized economy.

Sawmill - highly versatile and valuable lumber if woodlot is available - or lumber may be bought from neighbors.

Decentralized sawmilling may obviate clear-cut lumber companies in a new economy. Many uses.

General

Wood construction is one of the earliest methods of building shelter.

As we continue our CEB building lumber has been purchased to construct the trusses and will be needed to ruff-in door and window jambs.

Current lumber production is highly concentrated industry save the specialty wood shops producing for novelty wood workers. Unsound harvesting practices and high transportation costs make commercial lumber environmentally costly. Timber can be locally harvested and with a simply designed, low cost sawmill we can produce fine quality lumber sustainably and economicaly.

Product Ecology

The ecological impacts of commercial logging are devastating. Much of that lumber consumed is harvested by means that are unsustainable clear cutting forests and devastate ecosystems. Timber is BIG business, the inertia the logging companies have continues the cycle of centralized production and unpractical philosophies of every growing industry. The sawmill we aim to develop has the capabilities to restore lumber as a local resource using local woodlot that is harvested in a responsible and sound way. Thinning of forest, fallen trees, cleared lots all afford the opportunity for usable lumber while the scraps and sawdust are used for fuel and/or mulch. This method lends itself to a closed circle product cycle that returns production to the masses.

Localization

Any ecosystem that has trees offers the opportunity for local production. Thinning of woodland promotes diversity and creates space for new trees to grow while preserving the ecosystems natural cycle.

The design for dis-assembly proposed enables the sawmill to be transported over the road and to the trees.

The potential for efficient midsized wood milling is no joke. With mill capabilities to produce 2400 linear foot of wood in a day, pretty reasonable, you may not see the lumber yard again. With a sawmill like this you will be friends with every farmer, woodworker, and forester in the area. Sawing your own lumber affords you the ability to create beautiful and quality planks for peanuts while offering piles of satisfaction.

Scaleability

How can the product scale to larger or smaller operations/enterprises.

Lifecycle Analysis

An analysis of the life of the product, its materials, and its effects. For example, the sawmill makes lumber from the local trees, and the wood decays and returns to the ground to be used by more trees.

Sawmill Design Rationale

Things the sawmill must be able to do.

• Must adhere to OSE Specifications. (Open documentation. Low cost and easy to manufacture/replicate. Design for life, disassembly, repair. Robust, multipurpose.)

• Must be able to cut about 2400-3000 linear feet of dimensional lumber per day.

• Must handle up to 3000 lb logs.

• Must cut 4x4s and flat 2x of large width.

Motor Rationale

• Must use hydraulic power from LifeTrac.

• Power is about 40 hp - available from 55 hp Deutz, at .72 system efficiency.

• Hydraulic motors utilize 24 gpm at up to 3600 PSI. Each motor is 40 hp, around 700 RPM.

• 2 Cushion valves are used for stopping in bidirectional configuration.

• 2 spool control valve needs to handle the full fluid flow (24 gpm) to each motor.

• To use power effectively, one should be able to control the amount of flow to each of the two

motors, from full power in one to full power in the other.

• Main blade RPM - 2000 RPM.
• Edger blades - 5000 RPM.
• Simple pulley system, with single pulley of 3x for main blade.
• Double pulley for edger blades, about 2.5 ratio for each.

Platform Function Rationale

• Needs a platform that will be able to hold the weight of the motors, pulley system, blades, and frame.
• The weight of the platform will be about 25 lb. per motor, etc for a total of about 200 lbs.
• The platform must be stable enough to make straight cuts.
• The platform should be able to roll in the x axis.
• The platform must move precisely and hold securely in the y and z axes.
• The y and z axis movements must be about 3-4 feet for large logs.

Function List

• blades with insert teeth would be best to use, but maybe expensive
• 2 edger blades on same axle
• 2 edger blades are adjustable
• Move onto hydraulic log handling later
• Move on to automatic sawmill operation with remote control, for ease of cutting.
• Allow for log turning in addition to taking slices out of the wood
• Safety cage around blades
• Blade cooling soapy water?
• Logs loaded with tractor loader
• Mechanism to secure log to track
• use bearings to ride on a flat track?

Sawmill Research

Sawmill sites

http://www.forestryforum.com/board/index.php/board,7.0.html

Local Sawmills

1. http://simpsons-nativehardwoods.com/page7.html - St. Joseph, MO
2. Watkins Sawmill - Stewartsville, MO - (816) 669-3218

General Sawmill Research

• So you want to build a sawmill

• Dimension sawmills appear to have the highest output - [1] - For production, a chainsaw mill can mill 200 to 400 board feet per day, a band mill can mill 800 to 2,000 board feet per day, swing mills can produce 1,500 to 3,000 board feet per day and dimension mills 2,000 to 4,000 board feet per day. A lot depends on log size, species and products being cut.

• Circular saw blades appear to be easy to manufacture, repair, and have a good lifetime- [2]

• Price comparison of sawmills-[3]

Bandsaw comparisons:

• http://www.woodweb.com/knowledge_base/Building_your_own_bandmill_maybe.html

• http://www.forestryforum.com/board/index.php?topic=30464.msg439220

Blade Research

• 30" blades seem too expensive for most operations, a 20" blade might work and be much more affordable currently.
• Cheapest 30" $1200 - [4]
  • Not! That's for concrete cutting
• Cheapest 20" $150 - [5]
• 
• blades with insertable teeth would be best - [6]

From the book "Circular Sawmills and their efficient operation":

SAW SPEED In general, for good saw performance, a rim speed of 8,000 to 9,000 feet per minute is recommended for sawing hardwoods; 10,000 to 11,000 f.p.m. for softwoods; and 6,000 to 7,000 f.p.m. for frozen woods. The relationship of saw diameter and saw speed necessary to attain a predetermined rim speed is given in table 15.

Saw Collar

From "Circular sawmills and their efficient operation":

SAW COLLARS For trouble-free saw operation, both saw collars must be identical and they must be of sufficient size to provide rigid support for the saw plate. Most saw collars are made with a recessed inner section and an outer bearing surface about 3/4-to 7/8-inch wide that contacts the saw plate.

Figure 7. – To insure proper support of the saw blade, collars should be machined with a .002- to .004-inch radial taper on their bearing surface toward the recess.

Saw collars should be machined to provide maximum support for the saw plate. Machining the bearing surfaces of each collar with a slight radial taper toward the collar recess will help to accomplish this (fig. 7). The outer periphery of the bearing surface will then make positive contact with the saw plate after the arbor nut has been tightened properly. The amount of taper should be from .002 to .044 inch in the width of the bearing surface.

Sawmill collaboration

Date: Wed, Jan 21, 2009 at 7:59 PM

Subject: Re: sawmill design To: Marcin Jakubowski <joseph.dolittle@gmail.com>

Hi Marcin,

Love the blender format, that is a great image. I think the blade size depends on the logs your cutting, on machines that I make, I give myself a range of blade sizes, 20-30" smaller is cheaper and easy to sharpen. Its a neat design, but still too complex. Why are you using pulleys on hydrolic motors, why not lovejoy right on the shaft? As your doing hydrolic motors, think like rack mounts and give the edger its own table and feed belt. They can be mounted to the headsaw if that is still desirable in the future when the head saw is running well, otherwise, you just pinch and tweak three blades instead of one in start test phase. Running a separate edger is a good idea, three blades is too much for a green miller to keep track of. Ten inch would work fine as edger, and depending on the wood to be cut so would 6". Check out sawmillexchange.com .

Benjamen

Sawmill - Design Calculations

Available Power

• Review of LifeTrac hydraulic power calculations - LifeTrac#Calculations - shows that we have total 29 gpm available at 3300 PSI, or a lower flow at 3600 PSI.

• Hydraulic power is defined as Flow x Pressure. The hydraulic power supplied by a pump: P in [bar] and Q in [lit/min] => (P x Q) / 600 [kW]. Ex. Pump delivers 180 [lit/min] and the P equals 250 [bar] => Pump power output = (180 x 250) / 600 = 75 [kW]. 75000W / 745.7 = 100.58hp

• • LifeTrac has 91 l/min available from the auxiliary hydraulics, and 228 bar - 91x228/600/.746 = about 46 hp.
    • 24 gallons/minute = 91 liters/minute (of 29 gpm total LifeTrac power, 5 is diverted into tractor steering)
    • 1 bar = 14.5 psi, 3300 PSI = 228 Bar

Power Distribution Between 2 Sets of Blades

The sawmill has 2 sets of blades: the main blade and the edger blades - see 3d picture - #3D_CAD_-_Using_Blender. Hydraulic power must be distributed to both sets. One motor powers the 2 edger blades, and another motor powers the main blade. Power - or hydraulic fluid flow - must be distributed to both sets of motors to accommodate various cutting scenarios:

• Assume that main blade is 20 inches in diameter, and edger blades are 10"
• Square lumber profiles, such as 2x2s and 4x4s (size in inches)
• Rectangular lumber profiles - such as 2x4s, 4x8s, up to 1x9s

• The case where square profiles are cut requires one cut by the main blade, and equivalent cuts by the edger blades. Since there are 2 edger blades, this requires the condition where the edger blades require twice as much power as the main blade. The power distribution strategy and motor sizing should allow for this. Power ratio of main (Pm) to edger (Pe) blades: Pm/Pe = 1/2

• In the extreme opposite case, such as when cutting 1x10, the power ratio is Pm/Pe = 5

• The middle case exists for 2x4s, 4x8x - where Pm/Pe = 1

Hydraulics Design for 2 Sets of Blades

The point is that flow control must exist where the amount of power that goes to each blade can be varied. Power is controlled by fluid flow rate - or a flow control valve in practice:

Would this valve from Surpluscenter [7] do?:

Hydraulic Motors

Edger Blades - 10"

Main Blade - 20"

Sawmill Design developments

See Sawmill Design Developments

Sawmill - Current Work

We have a hydraulically-driven PTO motor as a start. It will be powered by LifeTrac. LifeTrac has this pump from Northerntool - [8]:

All hoses are already available - it is part of our flexible open source tractor infrastructure. Here are the motor specifications, from Surpluscenter.com:

Here is the hookup diagram:

Note: Since we have 3600 PSI available, we can run 2 of these motors in series to match available power more closely.

A very preliminary prototype drawing, top view:

3D CAD - Using Blender

Preliminary 3d pictures of the sawmill:

Sawmill Deployment

Implementation

With design rationale, put it up for review on Red Pages

Build space frame

Purchase one blade, 30", 2 blades, 12"

Build cutting head - gear up the blade

Install all safety devices before operating

Test sawmill operation without blades attached

Start with unidirectional cutting head, move on to bidirectional by upgrade

Bill of Materials

See Sawmill Bill of Materials

Development Work Template

1. Sawmill - Product Definition
   1. Sawmill - General
   2. Sawmill - General Scope
   3. Sawmill - Product Ecology
      1. Sawmill - Localization
      2. Sawmill - Scaleability
      3. Sawmill - Analysis of Scale
      4. Sawmill - Lifecycle Analysis
   4. Sawmill - Enterprise Options
   5. Sawmill - Development Approach
      1. Sawmill - Timeline
      2. Sawmill - Development Budget
         1. Sawmill - Value Spent
         2. Sawmill - Value available
         3. Sawmill - Value needed
   6. Sawmill - Deliverables and Product Specifications
   7. Sawmill - Industry Standards
   8. Sawmill - Market and Market Segmentation
   9. Sawmill - Salient Features and Keys to Success
2. Sawmill - Design Evolution
3. Sawmill - Technical Design
   1. Sawmill - Product System Design
      1. Sawmill - Diagrams and Conceptual Drawings
         1. Sawmill - Pattern Language Icons
         2. Sawmill - Structural Diagram
         3. Sawmill - Funcional or Process Diagram
         4. Sawmill - Workflow
      2. Sawmill - Technical Issues
      3. Sawmill - Deployment Strategy
      4. Sawmill - Performance specifications
      5. Sawmill - Calculations
         1. Sawmill - Design Calculations
         2. Sawmill - Yields
         3. Sawmill - Rates
         4. Sawmill - Structural Calculations
         5. Sawmill - Power Requirements
         6. Sawmill - Ergonomics of Production
         7. Sawmill -Time Requirements
         8. Sawmill - Economic Breakeven Analysis
         9. Sawmill - Scaleability Calculations
         10. Sawmill - Growth Calculations
      6. Sawmill - Technical Drawings and CAD
      7. Sawmill - CAM Files
   2. Sawmill - Component Design
      1. Sawmill - Diagrams
      2. Sawmill - Conceptual drawings
      3. Sawmill - Performance specifications
      4. Sawmill - Performance calculations
      5. Sawmill - Technical drawings and CAD
      6. Sawmill - CAM files whenever available
   3. Sawmill - Subcomponents
4. Sawmill - Deployment and Results
   1. Sawmill - Production steps
   2. Sawmill - Flexible Fabrication or Production
   3. Sawmill - Bill of materials
   4. Sawmill - Pictures and Video
   5. Sawmill - Data
5. Sawmill - Documentation and Education
   1. Sawmill - Documentation
   2. Sawmill - Enterprise Plans
6. Sawmill - Resource Development
   1. Sawmill - Identifying Stakeholders
      1. Sawmill - Information Collaboration
         1. Sawmill - Wiki Markup
         2. Sawmill - Addition of Supporting References
         3. Sawmill - Production of diagrams, flowcharts, 3D computer models, and other qualitative information architecture
         4. Sawmill - Technical Calculations, Drawings, CAD, CAM, other
      2. Sawmill - Prototyping
      3. Sawmill - Funding
      4. Sawmill - Preordering working products
      5. Sawmill - Grantwriting
      6. Sawmill - Publicity
      7. Sawmill - User/Fabricator Training and Accreditation
      8. Sawmill - Standards and Certification Developmen
      9. CEB - Other
   2. Sawmill - Grantwriting
      1. Sawmill - Volunteer grantwriters
      2. Sawmill - Professional, Outcome-Based Grantwriters
   3. Sawmill - Collaborative Stakeholder Funding
   4. Sawmill - Tool and Material Donations
   5. Sawmill - Charitable Contributions