Choosing the Right Sign Stakes: A Buyer’s Guide

Choosing the Right Lawn Sign Stakes: A Buyer’s Guide

Sign stakes are important for displaying signs for various purposes like real estate, political campaigns, events, or retail promotions. Choosing the right sign stakes can make your sign more visible and durable, helping it last longer in different weather conditions. This buyer’s guide will navigate the various options and help you select the best sign stakes for your needs.

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Understanding the Basics of Yard Sign Stakes

Before diving into the specifics, let’s get a basic understanding of what sign stakes are and their purpose.

Sign stakes, also called sign holders, are structures that hold and display lightweight signs like corrugated plastic signs. They are typically inserted into the ground and can vary in material, size, and design, each offering different benefits depending on the use case.

Types of Sign Stakes

• H-Shaped Sign Stakes: These are the most common types and are known for their durability and easy installation.
• Plastic Sign Holders: These are designed specifically for corrugated plastic signs and are ideal for temporary signage.
• Heavy-Duty Sign Stakes: Made for long-term applications, these stakes can withstand harsher weather conditions and repeated use.

Key Considerations When Choosing Sign Stakes

When selecting sign stakes, several factors must be considered to ensure you make the right choice for your needs.

Material and Durability

The material used for the yard stakes for signs plays a critical role in its durability. Common materials include metal, plastic, and wood. Metal stakes, especially those made of steel or aluminum, tend to offer the best durability and are resistant to rust and corrosion. Plastic stakes are lightweight and may be a cost-effective option for short-term use. Wooden stakes are less common due to their susceptibility to weather damage.

Size and Portability

Consider the size of your sign and the portability of the stakes. Larger signs may require sturdier, taller stakes for proper support, while smaller signs can use more lightweight options. If you need to move your signs often, portability will be a crucial factor.

Installation Ease

The ease of installation can save time and effort, especially if you’re placing multiple signs. H-shaped sign stakes, for example, can be quickly pushed into soft ground without requiring additional tools.

Visibility

Sign stakes should enhance the visibility of your sign. Ensure that the height and design of the stake do not obstruct the message you’re trying to convey. Adjustable or taller stakes can be beneficial for increasing visibility from a distance.

Cost-Effectiveness

Budget is always a consideration. While it may be tempting to go for the cheapest option, investing in more durable stakes can be more cost-effective in the long run, especially for signs that need to be displayed for extended periods.

Popular Types of Lawn Sign Stakes

H-Shaped Sign Holders

H-shaped sign holders are favored for their balance of stability and ease of use. They are typically made from wire or metal and are designed to hold corrugated plastic signs securely.

Pros:

• Good stability and support for various sizes
• Easy to insert into the ground
• galvanized for rust resistance

Cons:

• Not always suitable for extremely windy conditions
• May not be the best choice for very large signs

Plastic Sign Holders

These holders, commonly refered to as Spider Stakes, are made with a plastic base with metal pins that provide a snug fit that helps to keep signs in place.

Pros:

• Lightweight and easy to transport
• Simple to insert into soft ground

Cons:

• Limited durability compared to metal options
• Not ideal for long-term or harsh weather conditions

Heavy-Duty Sign Stakes

For signs that need to withstand the test of time and harsh weather, heavy-duty sign stakes are the way to go. Also known as Goal Post Stakes, they are made with a 3/4″ thick steel base with a 9 guage top for the standard 4 mm corrugated plastic to slid over.

Pros:

• Excellent durability and stability
• Can support larger, heavier signs
• More resistant to wind and weather

Cons:

• Typically more expensive
• Heavier and less portable

Installation Tips and Best Practices

Preparing the Ground

Before installation, ensure the ground is soft enough to insert the stakes for yard signs without bending them. Use water to soften hard soil if necessary. For extremely hard ground it may be necessary to predrill the hole with cordless drill.

Proper Placement

Position your signs in high-traffic areas for maximum visibility but be mindful of local regulations and property lines.

Sign Security

Make sure the sign is securely attached to the stake to prevent it from blowing away or becoming damaged.

Maintenance

Regularly check your signs and stakes for any wear or damage, especially after severe weather conditions.

Where to Buy Sign Stakes

Sign stakes can be purchased from a variety of sources:

• Local Hardware Stores: You can find basic yard sign stakes at most hardware stores.
• Specialty Sign Shops: These shops often offer a wider variety of sign holders and can provide expert advice.
• Online Retailers: Online stores may offer competitive pricing and a broad selection, but be sure to check reviews and return policies.

Conclusion

Choosing the right sign holder is essential for the effective display and longevity of your corrugated signs. By considering the factors outlined in this guide, such as material, size, visibility, and cost, you can select the lawn stakes that best suit your requirements. Whether you opt for H-shaped holders, plasic holders, or heavy-duty stakes, the key is to ensure that your signs remain prominent and intact for as long as you need them.

Remember, the right yard sign stake not only supports your sign but also represents the attention to detail and care you put into your message. With the right choice, your signs will stand out and endure, delivering your message effectively to your intended audience.

For information on selecting the right sign material and placement check out our post: The Ultimate Guide to Cheap Lawn Signs: Tips for Design, Material, and Placement.

Sand, snow, soil, rock, gravel, tundra, tent platform… so many substrates, so many stakes, so many choices!

Of all backpacking gear, tent stakes are one of the most important… and fraught! They make the difference between a secure night’s sleep in wild weather and a miserable one spent in and out of the tent as it collapses around you. Battling a flapping tent in pouring rain is not fun. We’ve all been there, haven’t we?

When it’s windy, stakes pulling out of the ground is the most common cause of tent failure. Such failures are 100% user error but, unfortunately, there is no one best tent stake. Rain, wind and varying substrates pose different challenges, so it’s essential to understand which stakes to choose, and why.

This article is aimed at backpackers with weight and space limitations in their packs, rather than car campers who can carry heavy steel anchors in their 4WDs.

This article, Part One, covers

• How stakes work – basic physics of surface area, friction, cohesion, force and implications for tents, because, when making gear choices, understanding how and why is always better than knowing only the what.

• Different types of stake (materials, shapes, weights and holding power)

Part Two covers

• Different substrates (sand, rock, stony, snow, sod, etc.) and which stakes to use

• Deadman anchors and other special techniques such as double staking and tent platform tips

• Guylines – material and connection tips

• Specific Pitching Considerations (number of stakes, mix of stakes and more)

How Stakes Work

When anchoring our tent, we have three considerations: soil properties, stake properties, and the forces imposed by our tent (a combination of tent size and shape, wind speed, and number of anchoring points).   This is applied physics 101, simplified by Geoff with a little help from Geotechnical Engineer Frank F, so my arts brain can follow. If I can, so can you! Grab a coffee and settle in! (Or, if you want to skip the why and how, jump down to Different Types of Stakes!).

Soil properties

Different soils have different properties but, for clarity, we’ve simplified soil types into coarse-grained and fine-grained to describe their primary physical characteristics.  In reality, soils are usually a mix of the two but, once you understand the principles, you can extrapolate to successfully adapt your anchoring. In the second article, we’ll describe staking in substrates that reflect what we often encounter: those with plentiful stones or tree roots, or covered in dense scrub or grasses, or snowy or frozen or patchy ones. But for now, let’s consider just those coarse- and fine-grained substrates.

Coarse-Grained Soils

Why is this important? In the field, gravity applies a natural force perpendicular to the soil particles ie the weight of the soil itself. Therefore,

in homogenous sandy or coarse-grained soil, the deeper you go the stronger it gets… but that doesn’t apply to all soil types.

Fine- Grained Soils

In fine-grained soils like clays, the particles are tiny and are held together by water surface tension and ionic attraction between the clay particles, rather than by physical interlocking - they are adhering to each other rather than being pushed together. This bond (called cohesion) must be broken for the soil to fail. Applying a perpIendicular force does not increase bond strength between soil particles, because the bond not physical. That means soil strength doesn’t increase with load (nor depth).

Soil Strength

Strength of interlocking and/or cohesion is referred to as the shear strength of soil.

For coarse-grained soils, the soil’s angle of friction is a measure of soil particle interlocking – the higher the angle, the stronger the interlocking.  Picture a pile of sand.  The natural slope of the pile is a measure of the angle of friction and interlocking – the steeper the slope the better for campers!  The angle of friction also describes the rate at which interlocking, or shear strength, increases when a perpendicular load is applied. In our case the perpendicular load is the weight of the soil itself so the force we can apply to the soil by our tent stake increases with depth.

Progressively more cohesive soils have progressively lower angles of friction so, as shear strength from physical interlocking reduces, the soil cohesion and moisture content becomes increasingly important. 

With our camping mix of fine- and coarse-grained substrates and soil strength depending on the combination, cohesive forces provide initial shear strength. Shear strength through physical interlocking increases, albeit at a slower rate, with depth.

So why is this important for us multiday hikers?

Friction is what keeps your tent stake in the ground!

There are two friction forces involved:

1. Friction between the tent stake and the soil

2. Friction (or cohesion) between the soil particles themselves

The friction between the tent stake and the soil is what resists the stake being pulled out by forces that act along the axis of the stake:

The friction between the stake and the soil is initially created by inserting the stake. The stake pushes sideways against the soil as it is inserted, and the soil itself pushes back (Newtons third law): a perpendicular force is being applied to the side of the stake. The soil is disturbed in this process, so the stake is easier to pull out than insert… but the harder it is to push in, the harder it is to pull out! This also explains why repeatedly reinserting a stake into the same hole in compacted or cohesive soil results in it being held less tightly. Of course, in loose soils such as sand dunes without any cohesive effects, and where particle interlocking is poor, this doesn’t apply.

The friction (or in clays adhesion) between the soil particles is what resists the stake being pulled out by forces perpendicular to the stake:

Implications for Staking your Tent:

Your stake can support forces on your tent by:

1. transferring loads along its axis to the soil and also

2. transferring loads sideways to the soil.

The larger the stake’s surface area, the larger the area of soil that the force is spread across ie, the more surface area, the better in soils with low shear strength.

You can increase surface area by choosing either a (1) wider or (2) longer stake.  For most soils (for practical purposes, everything other than pure clay) soil strength increases with depth so there is an additional benefit from having a longer stake.   It is therefore usually better to increase our surface area by choosing a longer rather than wider stake, up to a point. Stakes that are too thin lack robustness, and many soils are shallow, so practical limits apply.

Stake Pull-out Strength or Holding Power

The following graphs illustrate the change in stake holding power for a round stake in sandy soil.

For purely cohesive soils like clays, stake pull-out strength increases linearly in relation to depth and also stake diameter. That is because the shear strength of purely cohesive soil doesn’t increase with depth as it does for coarse-grained soils.

Contact us to discuss your requirements of u shaped ground stakes. Our experienced sales team can help you identify the options that best suit your needs.

Purely cohesive? Well, that’s uncommon. Soils are often a mixture of sand, loam, clay and gravel so they have some cohesive properties.  Now you understand why most reputable stake articles recommend longer stakes over shorter ones if you’re looking for holding power.

Longer thinner stakes also have more holding power than shorter fatter stakes of similar shape. For example: a 175mm long, 5mm diameter round stake, has a similar holding power to an 150mm long, 8 mm diameter round stake, but is much lighter. So, for holding power per gram, it’s better to go with the longer stake, even though it has a smaller diameter.  The same logic applies to other uniform shapes – but again you reach a point when the cross section becomes too small to be practical!

In the examples above, a round stake simplified concepts.  However, in addition to embedment depth, the stake’s surface area and perimeter contacting soil are important too. That’s easy for a round stake because diameter is a useful measure of both.  Other stake shapes may have larger perimeters or surface areas, but that doesn’t necessarily mean all of the stake is in effective contact with the soil. Stakes with clean uniform shapes such as round, Y, Vs and even square stakes are easy to insert without significantly disturbing the soil. This means all the stake’s surface area is utilised, maximising friction forces between soil and stake. A more complex-shaped stake does not always lead to a higher pull-out strength.

Just Add Water

Water has complex interactions with soil, from increasing cohesion in sand — imagine building a castle with completely dry sand! — to decreasing it in some clays (hard baked pans you can barely get a stake into versus soft, sticky mud). A detailed explanation is beyond the scope of this article but, if you expect rain in any but sandy soils, err on the side of caution as soil strength is more likely to decrease than increase.

Importance of Stake Angle:

We’ve all read different recommendations from vertical to 45 degrees, but there is rarely an explanation as to why, other than “has more holding power”.

The balance between the axial and perpendicular forces being transferred by the stake to the ground is influenced by:

1. the angle of the guyline or tent stakeout point to the ground, and also

2. the angle of the stake to the ground (and hence angle of stake to guyline).  

Consider the following stake-to-guyline configurations, each with the same tension force along the guy line:

1. Guyline extends from tent at an angle of 45 degrees to the ground, stake is inserted parallel to the guyline.

It would be useful to know if and how soil to stake friction compares with soil-to-soil friction before we set up out tent and decide what angle we install the guy rope and what angle to insert the stake!  Whilst we can’t do any field strength testing before we set up our tent, we can observe the soil on which we are pitching.

If we extrapolate data from circular piles, we can conclude that:

• For coarse-grained soils with no cohesive resistance, soil-to-soil friction resistance will be significantly greater that the soil to stake resistance, possible by a factor of three or more.

• For cohesive soils such as clays the soil-to-soil friction resistance will be higher, but only by between 20 to 50%.

So, when we insert stakes, we are most likely to be best off if we bias stake loading to utilise soil-to-soil frictional resistance, but not by too much.

In practical terms this means:

• Guylines should be as flat an angle to the ground as practicable (ie longer is better, with limitations for non-freestanding tents), and

• Stakes should be placed at a slight (between 5 and 20 degrees) angle off vertical.

With the 45 degree stake, the soil very quickly fractures near the surface and the rotation process doesn’t slow or pause: total failure occurs in one continuous process at around the 8 kilogram mark. The failures held true for all repetitions for both configurations.

Notice that the 15 degree stake holds firm after an initial small movement as the stake mobilises the shear strength of soil near its base as it begins to pivot. The stake stayed at this point from around the 8 to 10kg mark and the stake continued to hold as increasing load was applied until it finally fails at 16 kilograms. That process was consistent for all the tests.

The Importance of a Taut Pitch

Pull tests like those above with continuous increasing pressure illustrate an important principle but ignore the fact that this is generally not how wind and tents transfer force to guylines and stakes. Instead, wind gusts cause a tugging motion that is amplified by acceleration forces of a loose pitch. These repeated tugs loosen soil around the stake, decreasing the soil to stake friction and therefore also holding power: we all do this ourselves when trying to remove a stuck stake. A taut pitch decreases those tugging forces and the chance of your stake loosening in the soil.

Am I better off using a longer stake or a second stake?

There’s no single answer!

In cohesive soil such as a clean clay, two 150mm long stakes have more holding power than one 200mm stake (see Part Two, Double Staking). But then you are unlikely to need an extra stake in cohesive soils.

In coarse-grained or sandy soil, a 200mm long stake is likely to be just as effective as two 150mm stakes. However, using either stake as a deadman anchor provides the best overall pull-out strength outcome in this soil.

These are expensive, strong and light. However, some are stupid light, so thin so as to bend when pushed into anything but the most perfect of soils (looking at you, titanium v-stakes with holes in them!). However, titanium stakes excel as either nails for hard soil, or as snow anchors, where the substrate is soft and the nature of the metal means big weight savings when a large surface area is required for holding power. Some snow hikers also prefer titanium because it bonds less tightly to frozen snow than aluminium, so stakes are easier to remove. The very strong 3D-printed Pioneer Titanium Y stake (Disclaimer: slowerhiking was sent one for testing) suits a wider range of substrates than other titanium stakes.

4. Carbon and Carbon core

Light carbon stakes are expensive and practical for limited substrates. We don’t recommend them for much of Australia’s hard, rocky soils: carbon is strong but prone to shattering, as when hammered in with a rock. If you regularly camp in places where you can push stakes in with your hand, they save lots of weight. Weight weenies can DIY carbon stakes at 2.4g each but wear a respirator: like asbestos, carbon dust fibres stay in lungs.

The best carbon core or hybrid stakes with aluminium sheathing, head and tips combine the best features of both these materials, are very light, and are worth considering in areas with soft-firm soil; the heads don’t lend themselves to hammering and you still need to baby these stakes a little. Some people use a thin needle or nail stake to make a pilot hole in hard soils before inserting the carbon core one.

5. Plastic

Cheap plastic tent stakes can be very strong and ideal for sand, but they are too bulky and heavy for backpackers who will generally prefer deadman anchors (see Part Two) in such substrates. Delta anchors are an exception (Part Two).

6. Wood

Of course we no longer buy wooden tent stakes, but most hikers have them at our disposal! Use a forked branch, break or whittle it so the fork is upside down to form the hook at the top, and sharpen the opposite end. Sticks also make excellent deadman anchors as you don’t need to disinter them! Wooden options are worth remembering if one of your stakes breaks or is lost.

Most budget tents come with this traditional thin tent stake with a hook or crook at the top, and they are also the first thing backpackers swap out after their first trip. This is because shepherd’s crook stakes have limited application and because the quality of supplied stakes is usually poor.

These stakes suit only hard or firm substrates as they have too little surface area to create sufficient friction and holding power in looser ones.  Because they are used in hard soils, their quality is even more important than for more generalist stakes because, especially in Australia with our baked and rocky substrates, you are more likely to need to hammer them in, rather than just pushing with your hand or sole of your boot. Cheap shepherd’s crooks instantly bend in this situation. Titanium wire stakes can be very strong, very light (about 5g), and thicker ones can be hammered in.

Shepherd’s crooks sometimes spin 180 degrees in insufficiently cohesive soils, allowing guylines to slip off. Inserting the stake deep enough to embed the tip of the hook helps prevent the stake from spinning.

2. Nail or Needle stakes

These stakes are for harder substrates; if you need them, and as the name suggests, you often need to hammer them in with a rock. Both tend to be very strong, particularly titanium ones which many hikers consider almost indestructible; our square profile 8g (0.28oz) aluminium Mont needle stakes  (discontinued) don’t spin and have been with us for many years. Both are relatively short compared to some other stakes but they don’t need length in such hard substrates.  The aluminium 10g (0.4oz), 15cm (6”) Nemo Airpin is an interesting take on the needle stake.

Nails bite through sandstone, some rock and even wood; they can be difficult to remove and although gram weenies discard pull cords from stakes, they are worth leaving on these!  They are particularly good in frozen ground and very stony ground where the thin diameter finds its way through the substrate; they are great in our local calcrete. Some people use them to make pilot holes in stony soil for larger stakes. They are almost impossible to bend; you may do it by pushing with your boot at the wrong angle rather than hammering.

Because many nail stakes have only a small lip at the top, care must be taken to angle them sufficiently so that the guyline doesn’t slip off, or to loop the guyline twice. However, there is unlikely to be any stake movement in the kinds of substrates they are used.

3. Tube Stakes aka Easton Stakes

Tube stakes are made of aluminium with a flattened head cap and a pointed tip. The 20.3cm (8”) ones weigh about 12g (0.4oz), 15cm (6”) ones about 10g (.35oz). At just 2g heavier, longer Eastons have significantly more holding power than shorter ones.

Others are made of carbon, with an aluminium tip and head, weighing just 6.6g (0.22 oz) whereas hybrid ones are comprised of carbon within an aluminium sheath  (15cm/6”) weighing just 5.5g/0.19oz). All are light, strong and stiff, with the aluminium ones reportedly the most durable.

At 8-9mm thick, these are all designed for soft to firm rather than hard ground. The aluminium ones handle being hammered in occasionally – the tops break off if you do it too often – and many hikers swear by them. Straight carbon versions need much softer substrates and collapse when hammered into hard ground.

In our experience, Eastons are versatile, handling tougher soils than aluminium shepherd’s hooks and even some titanium v stakes, with similar holding power to the latter with comparable length.

4. Snow/Sand/Blizzard stake

As you expect just by looking at them, these stakes are for loose substrates such as scree, gravel, snow and sand at the opposite end of the spectrum than for shepherd’s hooks and nails. Snow and sand stakes are long and wide with a large concave surface area; some have holes to reduce weight.  You can guy to these holes instead of the top of the stake so the guyline attaches below the soil surface to increase the holding power of the stake. In soft snow or very loose sand, completely bury these stakes deadman style to exponentially increase their holding power (see Deadman Anchors in Part Two). Deadman anchoring also works with much lighter stakes and objects, and is preferable if you want to carry less weight.

Because these stakes are only pushed or buried, never hammered in, forces are widely spread rather than concentrated, so cheap aluminium sand stakes may be a little heavier than expensive ones, but every bit as durable.  

Sand stakes are excellent for digging cat holes in dirt to bury your poo! We have a set of the discontinued (but still available) small Toughstakes, which even resemble small spades. However, they are heavy at 39g (1.38oz), though the weight is less significant if you carry one instead of a poo trowel such as the Deuce of Spades (17g/.6oz).  

Snow pickets made of channel aluminium are too long and heavy for hikers, who will adapt their skis, snow shoes or hiking poles instead.

5. Y-stakes or Groundhogs

Unlike shepherd’s hooks and snow stakes designed for specific substrates, aluminium Y stakes (Y shaped in cross section) are all-rounders and hugely popular for this reason: you can get by in much of Australia using them.  At a pinch, they can be bashed into hard ground, or pushed deep into softer ground.  However, aluminium ones are not designed to be repeatedly hammered in with rocks, and doing this too often results in the head breaking off. They can also be very difficult to get into the kinds of rocky soils we have in Australia, as they are too thick to find their way between the stones.

The most famous of these stakes, the 19cm (7.48”), 13g (.46oz)  MSR groundhog, has a barely noticeable curvature on the bottom of each of the three flanges, causing the stake to twist slightly as it is pushed into the soil, increasing its holding power. Cheaper ones often lack this feature. The Groundhog’s flanges are also tapered, so overall the stakes are thicker, stiffer and stronger; they are also made of strong aluminium alloy. If you expect to occasionally hammer in your Y stakes, it is worth buying quality ones rather than cheap knockoffs.

Groundhogs come in two sizes; at 10g the 15cm (6”) Minis are lighter than the full-sized ones, suit firm ground (firmer than the 19cm ones) and are a good option for ultralight hikers. With a significantly thinner diameter, they penetrate rocky soil better than full-sized ones.

Teragon Gear manufacture the Pioneer, a 150mm (5.9”)n 3D printed titanium Y-stake (Disclaimer: slowerhiking was sent one for testing). It is the equivalent of a mini Groundhog but weighs only 5.1g (0.18 oz), half the weight of a mini Groundhog. The Pioneer has a ‘limited lifetime warrantee’ but we have not yet had it for long enough to determine durability. Thus far the head with its flat top and Y-beam construction at the neck has held up extremely well to hammering with rocks and the tip has not blunted: it has the highest strength-to-weight ratio of any metal tent stake on the market. At USD$20 per stake these are expensive but if you are cashed up and weight and strength are the most important criteria for you, these stakes are the lightest all-rounder stake choice for ultralight tarps and DCF shelters (durability not yet known). We’d like to see a full-sized one for even more significant weight savings over standard Groundhogs.

The 20cm (7.9”)  STS Ground Control Tent stake (14g/0.5oz) has three guy attachment cutouts so you can utilise lower ones to reduce leverage in soils where you can’t push the stake all the way in; it’s also clear that the cutouts decrease the strength of the stake and you would want to be extremely careful hammering them in. However, with just one cut out at the head rather than three — one on each flange — the head is likely to be stronger than that of the Groundhog.

6. X stakes

These are an X shape in profile, and they have similar characteristics to Y stakes, but are shorter and lighter. Many mid-range knockoff tents such as Naturehike come with these stakes. However, it’s likely that the complex perimeter disturbs and fractures soil more on insertion than do less complex shapes, potentially reducing the X stake’s holding power.

7. V-stake (aka J-stake, named after the founder of DAC)

V-stakes are popular for soft to firm substrates, but not so much rocky ones. V-stakes have a large surface area but little weight, so the material these stakes are made of, and their construction, makes a big difference to their strength. High quality ones, such as DAC aluminium stakes (12g, 16cm), are thicker in the centre of the V, making for a significantly stronger stake than one the same thickness throughout. DAC aluminium alloy is also high quality; cheap V-stakes are not a great choice because they are not used only in the softest substrates and need to be strong. DAC J stakes can be hammered into most soil and even wood. They also have a tiny notch partway down the shank for the guy loop if you can’t get the stake all the way in.

Marginally lighter at 11g (.39oz) for 16.5cm (1.97”) are these titanium V stakes:

Delta anchors use an interesting principle where forces are transferred so that they act in a similar way to a deadman. The ones most commonly used by backpackers, primarily in the UK, are a whopping 49g each. Titan ground anchors are aluminium deltas that work on the same principle but with a large flat surface area like snow anchors; the smallest weighs 22g (0.78oz).

Why carry such stakes? Because delta anchors are excellent in just one particular kind of substrate – spongey, soft, shallow sod over rock. You need long stakes for holding power in the spongey turf, but long stakes can’t be pushed all the way in, and the substrate is too shallow for burying deadman anchors, which would in any case be precluded by LNT principles with this kind of vegetation. Nor are rocks lying on the surface for modified deadman anchoring. Here is the cheap Australian version (bulky and even heavier at 60g each). In our opinion, these aren’t useful for Australian backpackers with our substrates.

10. Other stakes

Interesting alternative designs come and go on the market (can you deduce a potential issue with these stakes?); whenever trying new tent stakes, consider the principles from part 1 of this article to determine where they will work best, and how best to deploy them.

Table 2: Tent Stakes, Weights and Substrates

Use this table only as a rough guide: as we have seen, not all stakes are equal, even when they are nominally the same. We’ve used examples from our stake bag and from online suppliers. Substrate gradations of Loose, Soft, Medium, Firm and Hard are subjective and are to indicate stake suitability relative to each other. Stake length and the presence of gravel, fibrous roots or rocks within the substrate also greatly impacts stake suitability. The following selections are for windy rather than still conditions: in the latter many of the stakes will hold in soft and even loose substrates.

Are you interested in learning more about hexagonal wire netting? Contact us today to secure an expert consultation!