Anchor Load Calculator

Anchor Load Calculator

Estimate total anchor load, force per leg, angle multiplier, and safety margin for tarp, awning, guyline, and camp rigging anchors.

Anchor presets

📏Load and anchor inputs

Use measured line tension if known; otherwise use the expected pull on the anchor system.
Wider included angles increase leg tension. Keep below 90° when possible.
Count only legs that are actually sharing load through the master point.
Use 1.0 for steady pull, 1.2-1.6 for gusts, and higher for abrupt shock loading.
0° direct pull, 90° corner redirect, 180° full turnaround.
Adds allowance for ground drag, edge friction, knots, wraps, and imperfect pull direction.
Use the weakest single component rating: stake, strap, shackle, bolt, or soil hold.
The calculator divides the entered rating by this factor before comparing to leg force.
Lower quality means fewer legs effectively share the load.
Reference values are planning placeholders; field conditions can reduce them sharply.

Anchor load results

Force per leg
0 lb
calculated per effective anchor leg
Total anchor load
0 lb
after dynamic, direction, and friction factors
Safety margin
0.0x
usable rating divided by force per leg
Angle multiplier
1.00x
from included anchor angle

🧱Anchor material/spec grid

250 lbAluminum stake
500 lbSteel stake
600 lbSand deadman
900 lbSnow picket
1,500 lb3/8 in bolt
2,200 lb1/2 in eye bolt
3,000 lbTree strap
5,000 lbRated anchor

📊Anchor angle multiplier table

Included angleLeg angle factorTwo-leg sharePractical note
1.00x50% each before quality factorNearly straight, most efficient
30°1.04x52% each before quality factorExcellent for balanced anchors
60°1.15x58% each before quality factorCommon target for field setups
90°1.41x71% each before quality factorHigh leg force, check margin
120°2.00x100% each before quality factorAvoid unless anchors are very strong
150°3.86x193% each before quality factorVery poor geometry for shared anchors

Direction change and friction table

Direction changeResultant load factorTypical useFriction allowance
0° direct1.00xStraight guyline or tie-out pull0-10% for clean alignment
60° bend1.00xLight corner bend5-15% for surface drag
90° redirect1.41xCorner pull or side-loaded line10-25% for wraps or edge contact
120° redirect1.73xWide redirected tension15-35% if line rubs
180° turnaround2.00xFull return around a point20-50% if not on a pulley

🔧Equalization quality table

Quality settingEffective share factorWhat it assumesWhen to use it
Poor0.55One leg may take most of the loadMismatched lengths, loose legs, bad alignment
Fair0.70Some load sharing but not balancedHand-tied field anchors with visible unevenness
Good0.85Most legs share after adjustmentAligned anchors with careful tensioning
Excellent0.95Near-even sharing across legsMeasured, symmetric, or well-equalized systems

Anchor reference table

Anchor typePlanning ratingBest load directionCommon weak point
Aluminum tent stake250 lb per stakeLow-angle guyline pullSoft soil or bending
Steel ground stake500 lb per stakeAxial pull with deep setLoose soil or shallow placement
Sand or snow deadman600 lb per anchorBuried broadside pullPoor burial depth or weak fill
Snow picket T-slot900 lb per picketBuried horizontal pullSoft snow and angle creep
3/8 in expansion bolt1,500 lb per boltRated axial or shear directionUnknown substrate or bad install
1/2 in forged eye bolt2,200 lb per eyeIn-line pull through eyeSide loading and thread engagement
Tree strap anchor3,000 lb per strapBroad wrap around sound trunkBark slip, abrasion, or buckle rating
Rated rigging anchor5,000 lb per pointManufacturer rated directionConnector mismatch or side loading

💡Anchor load tips

Angle tip: Narrower anchor angles reduce leg force fast. If the margin is low, move anchors farther in line with the pull before adding more legs.
Rating tip: Compare the result to the weakest single part, not the strongest. Soil hold, knots, side loading, and abrasion can control the real limit.

When you set up a tarp or a ridge line in the wind, you must think about how the force of the wind travels to each anchor point. The force of the wind dont just push against the tarp or ridge line; it also travels the distance to the anchor points. Many times, people will guess at how much force the anchor points will hold.

People will select a stake based off the feeling of the stake in their hand, not on the force that it can hold. Anchor systems can multiply the force that is applied to them in ways that is difficult for people to understand. For example, if the wind applies the force equally to two legs of an anchor system, each leg will experience half the force of the total force of the wind.

Keeping Your Tarp Anchors Safe in Wind

If the same force is applied to three legs, each leg will experience one-third the total force of the wind. The tension in each of these legs will increase with the angle between each leg. The calculator in this article can help you determine the force that will be placed on each leg of your anchor system by entering the angle of your setup, the number of legs, and the quality of the equalization system that you use.

The strength of the soil that your anchors will be placed into will also impact the force that they can hold. For example, if a tent stake is rated for a certain amount of weight when placed into firm ground, it may not hold that same force if it is placed into sandy or wet loam soil. If you use tree straps to anchor your tarp or ridge line, they may fail if the straps either buckle or the bark slip.

A reference table of the different types of hardware is provided for planning your anchor system. The values in that table are ideal values only and will usually be lower in your actual situation. Use the safety factor input in the calculator to provide some room for the force of the wind to be greater than expected and for the strength of the soil to be less than expected.

Dynamic loading is another type of loading that people often do not consider. The force of the wind may be steady while everyone is standing still on the ground. However, if the wind gusts the tarp or if someone stumbles into a hammock, that force will temporarily increase.

The dynamic load multiplier field in the calculator can help you account for such an increase in force. For instance, if you expect gusts of that strength on your tarp, a multiplier of 1.4 is applied to the force of the wind. Higher multipliers can be used for other dynamic loads such such as people moving in the tarp.

The friction allowance accounts for the force loss that occurs when the line runs over the edge of a tarp or hammock or across tree bark. These losses are cumulative along the length of the line. The quality of the equalization system will impact the force that each of the anchor points will experience.

If each of the anchor legs is not of equal length or tension, each of the anchor points will not experience an even distribution of the force of the wind. Use the quality factor in the calculator to set the quality of your equalization system. For example, if you have a three-leg system and the tension between each of the legs is not even, one of the legs will experience more force than the others.

If the system uses three legs of unequal tension, it is as if the system is using only two legs to support the tarp or ridge line. This will show up in the calculator in the effective leg count after the quality factor is entered. Changes to the direction of the lines will create a multiplier to the force that is placed onto each anchor point.

If each of the lines are redirected 90 degrees from the direction of the wind load, the anchor points will experience a roughly doubling of the force that is placed onto each point. The same can be said for lines that are redirected 180 degrees. These values are shown in the direction change table in the calculator.

Many people do not consider the forces that are placed onto the anchor points created from these line changes. The calculator includes the angle of each of these changes in its force calculations before it distributes the calculated force onto each leg of the anchor system. The geometry of the anchors will determine the force that is placed onto each of the anchor points.

If a leg of a tarp or ridge line system is overloaded, you can lower the force on each anchor point by moving the anchors farther down the line. This narrowing of the angle between each line will lower the force more quickly than adding another leg to the system. In addition to moving the anchor points, you can upgrade the weakest components of the system to provide enough force to handle the load of the tarp or ridge line.

The safety margin output will show you whether or not the force calculations of the system are above the safety factor that was selected for that system. If the safety margin is below 1.5, then small changes in the force of the wind or the placement of the anchors may push the system past its limit. Field conditions will degrade the strength of the system over time.

Force placed into soil that is wet, frozen, or subjected to repeated loading will reduce the capacity of that anchor system over time. It is a good idea to check the anchors after the first night of weather conditions. Checking the anchors is more useful than any calculation provided in this article.

However, the calculations that are provided before setting up the stakes will help you to understand the different variables of your system. The force calculations can then be compared to the hardware components in your current kit. Actualy, the calculations should of helped you to understand the different variables of your system.

Check the anchors after the first night of weather conditions, checking them is more useful than any calculation provided in this article. Its important to make sure you’re anchors are secure. Youll want to make sure the soil isnt too soft for the luxurius tent setup.

The furnitures weight might also matter.

Anchor Load Calculator

Leave a Comment