Arvin mentioned some specs for a new osage flight bow.
and as I am learning to work with Virtualbow along with learning about what makes a bow good for flight, I thought it would make for a "design along" to post as I go. Comments and questions and insights welcome.
Arvins design:
Single piece selfbow
62" NTN
50# @ 25"
7" brace height
1.5" flipped tips
8" between fades
Virtualbow can be downloaded from
https://www.virtualbow.org/https://www.virtualbow.org/files/user-manual/ explains the program in detail
When Virtualbow first opens, it presents with a multi pane window. The upper right pane shows the bow in Back view, side view, single limb view or with both limbs, as selected by the buttons in the lower part of the pane. One can also zoom or rotate. The lower right pane will show plots when Items are highlighted/ selected in the left sidepane.
Below are some typical views when working with the program functions.
units_moe.jpg Two features are demonstrated in the first screenshot.
1. Selecting the "options" dropdown in the upper left pops up the units dialog where you can choose your default units, either metric (SI) or (US).
2. In the upper half of the left hand sidebar, by highlighting materiels > new materiels, the lower section in the side bar presents text entry fields to set Rho (materiel density) and E (stiffness). Having the correct Rho value is not required for simple "static" design but will need to be set properly when generating "dynamic" outputs.
The stiffness of the materiel is neccessary for knowing the draweight of a design. It is set on the E line by clicking on and resetting the desired MOE (modulus of elasticity). It is has been unchanged in the example below, as it is close to the book value for osage. Actual bend testing of a ripping from the stave will determine a closer value and will be done before the Arvins design is finalized.
MOE is explained in more detail at
https://www.wood-database.com/wood-articles/modulus-of-elasticity/ and book values for various woods can be found by searching in the database. From the wood database, one might find an potential Elastic Modulus or MOE of 1,350,000 lbf/in2. Clicking the existing E in the sidebar allows one to enter 1,350,000 directly. The program will display in scientific notation once the value is entered.
The values from the database are obtained by averaging across many samples of various densities at 12% MC. If one has a primo stave with good rings at a 6% MC and applies heat treatment on the belly, then using a book value in the program could likely indicate the need for a wider stave then neccesary.
dimensions.jpg brace height and draw length are set in the left hand sidebar by
highlighting "dimensions". Enter your preferences in the lower sidebar.
thickness.jpg Virtualbow is optimized for designing laminate bows. Each laminate materiel can be defined as a "layer" with its own MOE and its own thicknesses.
In this designalong, Arvins selfbow being from a single materiel, the thickness profile will include the handle, fades and limbs all in a single layer
Highlight layer > newlayer. A table will appear in the lower sidebar. Entries in the lower table for a 31" limb are explained line by line as follows.
1. 0 is center of bow. 2 specs the depth of handle at center of bow in inches.
2. In the left hand column of this table, the distance out from the center of bow is given in
percentage. making the percentage entries in the tables to need some calculation. Keeping in mind that we are designing a 62" bow, and each limb will be 31", the second row of the table is calculated thus. For a 4-5/8" handle on the bow, the half length would be 2-5/16" on each limb. Divide 2-5/16"(2.31) by 31" to get .075 which is entered as 7.5 in the left box and the right box keeps the handle depth at 2".
13% at .87" thick is an arbitrary point I chose for Arvins proposed handle ramp. It helps set the slope and shape of the ramp where the handle thichness transitions into the limb.
Choose a percentage that works best for you if needed. Raise or lower the thickness (.87") in the second box with the small arrows that appear when you double click inside the box.
The 13 in the first box on the line can also be raised or lowered also with up/down arrows in it's box. Shape the ramp to your liking by adjusting both values.
22% is where the thickness taper becomes fully working.
Again, divide the distance out on the limb that you desire the limb to start fully working by the overall limb length. 6.8" / 31" = .22 or 22 in the table when entered as a percentage. .42" in the second box is a thickness you estimate for the beginning of the limb thickness taper.
The last row defines the the trial thickness at the nock. 100% of .31"
The actual limb length of 31" will be specified innthe table and plot whan the "profile" line is highlighted as explained in the next post below.
f1width(1).jpg Illustrates setting limb widths. Highlighting "width" in the sidebar brings up a width plot and tables in the lowers sidebar for setting the width values in inches. Again, points along the limb are again shown as percentages of the total limb length. Arvins design calls for a 1.5" wide handle, 8" (13%) from the widest part of the fades to the" widest part of the fades, then straight for just under 7" (35%), then into a willow leaf taper to 5/16" at the nock. Arvin mentioned 4" straight section before tapering, and that can be done also. A straight taper can be had too. It just makes for small changes of the location of where the maximum stress occurs in the limb.
