FEMA 320- Taking Shelter From the Storm: Building a Safe Room Inside Your House


Introduction 


Every year, tornadoes, hurricanes, and other extreme windstorms injure and kill people, 
and damage millions of dollars worth of property in the United States. Even so, more 
and more people build houses in tornado- and hurricane-prone areas each year, 
possibly putting themselves into the path of such storms.
Having a shelter, or a safe room, built into your house can help you protect yourself and 
your family from injury or death caused by the dangerous forces of extreme winds. It 
can also relieve some of the anxiety created by the threat of an oncoming tornado or 
hurricane.

Should you consider building a shelter in your house to protect yourself and your family 
during a tornado or hurricane? The answer depends on your answers to many 
questions, including:

¥ Do you live in a high-risk area?

¥ How quickly can you reach safe shelter during extreme winds?

¥ What level of safety do you want to provide?

¥ What is the cost of a shelter?


This booklet will help you answer these and other questions so you can decide how best 
to protect yourself and your family. It includes the results of research that has been 
underway for more than 20 years, by Texas Tech  University's Wind Engineering 
Research Center (WERC) and other wind engineering research facilities, on the effects 
of extreme winds on buildings. 

This booklet also provides shelter designs that will show you and your 
builder/contractor how to construct a shelter underneath a new house, in the basement 
of a new house, or in an interior room of a new house, or how to modify an existing 
house to add a shelter in one of these areas. These shelters are designed to protect you 
and your family from the high winds expected during tornadoes and hurricanes and 
from ßying debris, such as wood studs, that tornadoes and hurricanes usually create.
The National Association of Home Builders (NAHB) Research Center has evaluated 
these designs for construction methods, materials, and costs. Engineers at Texas Tech 
University have conÞrmed the design requirements for the expected forces from wind 
pressure and the impact of typical ßying debris. The shelters are designed with life 
safety as the primary consideration.











Section I: 
Understanding the 
Hazard


Almost every state in the United States has been affected by extreme windstorms such 
as tornadoes and hurricanes. Virtually every state has been affected by a 
"considerable" tornado (see the terms in Table I.1). All Atlantic and Gulf of Mexico 
coastal areas in the United States - including coastal areas of Puerto Rico and the U.S. 
Virgin Islands - and coastal areas of Hawaii have been affected by hurricanes. Even in 
states not normally considered to be susceptible to extreme windstorms, there are areas 
that experience dangerous high winds. These areas are typically near mountain ranges, 
and include the PaciÞc Northwest coast.


What Is a Tornado?

Tornadoes are categorized by the Fujita scale (see Table I.1). They typically occur in 
the spring and summer months, but can occur at any time in any part of the country. 
Tornadoes are sometimes spawned by hurricanes. 



Category / Typical Damage

F0 Light: Chimneys are damaged, tree branches are broken, shallow-rooted trees are 
toppled.


F1 Moderate: Roof surfaces are peeled off, windows are broken, some tree trunks are 
snapped, unanchored mobile homes are overturned, attached garages may be 
destroyed.

F2 Considerable: Roof structures are damaged, mobile homes are destroyed, debris 
becomes airborne (missiles are generated), large trees are snapped or uprooted.

F3 Severe: Roofs and some walls are torn from structures, some small buildings are 
destroyed, non-reinforced masonry buildings are destroyed, most trees in forest are 
uprooted.

F4 Devastating: Well-constructed houses are destroyed, some structures are lifted from 
foundations and blown some distance, cars are blown some distance, large debris 
becomes airborne.

F5 Incredible: Strong frame houses are lifted from foundations, reinforced concrete 
structures are damaged, automobile-sized missiles become airborne, trees are 
completely debarked.

Not all parts of each state are at equal risk from tornadoes. For example, while Texas 
has the highest number of recorded tornadoes, the state's least tornado-prone 
area-along the Gulf Coast-has been hit by fewer tornadoes than northeastern 
Arkansas. Comparing the numbers of tornadoes recorded in different areas within a 
state can give you a better understanding of the potential tornado activity in those areas. 

Figure I.1 shows the summary of recorded F3, F4, and F5 tornadoes per 3,700 square 
miles in the United States and its possessions and territories.



What Is a Hurricane?

Hurricanes are categorized by the SafÞr-Simpson scale (see Table I.2).

Category / Typical Damage

C1 Minimal: Damage is done primarily to shrubbery and trees, unanchored mobile 
homes are damaged, some signs are damaged, no real damage is done to structures.

C2  Moderate: Some trees are toppled, some roof coverings are damaged, major 
damage is done to mobile homes.

C3  Extensive: Large trees are toppled, some structural damage is done to roofs, 
mobile homes are destroyed, structural damage is done to small homes and utility 
buildings.

C4  Extreme: Extensive damage is done to roofs, windows, and doors; roof systems on 
small buildings completely fail; some curtain walls fail.

C5  Catastrophic: Roof damage is considerable and widespread, window and door 
damage is severe, there are extensive glass failures, some complete buildings fail.


In the United States, 158 hurricanes were recorded to have made landfall between 
1900 and 1996. Hurricanes have made landfall in Florida more than in any other state. 
The second most hurricane-affected state is Texas, but every state on the Gulf Coast 
and bordering the Atlantic Ocean, as well as U.S. island possessions and territories, are 
susceptible to damage caused by hurricanes.
In recent years, the U.S. territories of American Samoa and Guam have been seriously 
affected by numerous tropical cyclones.



Do You Need a Shelter?

On the basis of 40 years of tornado history and more than 100 years of hurricane 
history, the United States has been divided into four zones that geographically reßect 
the number and strength of extreme windstorms. Figure I.2 shows these four zones. 
Zone IV has experienced the most and the strongest tornado activity. Zone III has 
experienced signiÞcant tornado activity and includes coastal areas that are susceptible 
to hurricanes. 

To learn more about the wind history for the area where you live, check with your local 
building ofÞcial, meteorologist, emergency management ofÞcial, or television weather 
reporter.

Your house is probably built in accordance with local building codes that consider the 
effects of minimum, "code-approved" design winds in your area. Building codes 
require that buildings be able to withstand a "design" wind event. A tornado or extreme 
hurricane can cause winds much greater than those on which local code requirements 
are based. Having a house built to "code" does not mean that your house can withstand 
wind from any event, no matter how extreme. The shelter designs in this booklet 
provide a place to seek safe shelter during these extreme wind events.
The worksheet on pages 7 and 8 will help you determine your level of risk from these 
extreme events and will assist you in your consideration of a shelter. If you decide that 
you need a shelter, Section II will help you and your builder/contractor plan your 
shelter.



DEFINITION
In this guide, the term missiles 
refers to debris and other objects picked up by the wind and moved with enough force 
to damage and even penetrate windows, doors, walls, and other parts of a building. In 
general, the stronger the wind, the larger and heavier the missiles it can carry and the 
greater the risk of severe damage. But even small stones, branches, and other lighter 
missiles can easily break glass doors and windows.



WARNING

A shelter designed to protect you and your family from a hurricane should not be built 
in an area expected to be ßooded during a hurricane. Residents of these hazardous 
coastal areas should abide by the warnings of their local emergency services personnel 
and evacuate to safer ground. The protection from wind provided by safe rooms and 
shelters is quickly negated when stranded homeowners Þnd themselves trapped by 
ßoodwaters. 
If you do not know whether your house is in a storm surge area or other area subject to 
ßooding, check the community service section of your local phone book for storm 
surge evacuation information or ask your local emergency management or ßoodplain 
management ofÞcial.


DEFINITION
In this guide, the term storm surge refers to the rise in the level of the ocean that results 
from the effects of wind and the drop in atmospheric pressure associated with 
hurricanes and other storms.




Homeowner's Worksheet: Assessing Your Risk

To complete the worksheet on the back of this page, refer to the tornado and wind zone 
maps on pages 3 and 6 (Figures I.1 and I.2). Using the map on page 3, note how many 
tornadoes were recorded per 3,700 square miles for the area where you live. Find the 
row on the worksheet that matches that number. Next, look at the map on page 6 and 
note the wind zone (I, II, III, or IV) in which you live. Find the matching column on the 
worksheet. Finally, Þnd the box inside the worksheet that lines up with both the number 
of tornadoes per 3,700 square miles in your area and your wind zone. The color of that 
box tells you the level of your risk from extreme winds and helps you decide whether to 
build a shelter.

For example, if you live in Jackson, Mississippi, you would see that Jackson is in an 
area shaded medium orange on the map on page 3. So according to the map key, the 
number of tornadoes per 3,700 square miles in the Jackson area is 11 - 15.




On the map on page 6, Jackson appears within the red-shaded area. The map key 
tells you that Jackson is in Wind Zone IV.
The box where the 11-15  row and the Zone IV column meet is shaded dark blue, 
which shows that you live in an area of high risk. A shelter is the preferred method of 
wind protection in high-risk areas. Note that some areas of low or 
moderate risk, shown as pale 
blue or medium blue in the 
worksheet, are within the region of 
the United States that is subject to 
hurricanes (see Figure I.2). If you 
live in this hurricane-susceptible 
region, your risk is considered 
high, even if the worksheet 
indicates only a moderate or 
low risk




Emergency Planning and Emergency Supply Kit

Whether or not you decide that you need a shelter in your house, you can take two 
important steps to protect yourself and your family during a hurricane or tornado: 
prepare an emergency plan and put an emergency supply kit together. If you decide to 
build a shelter, your emergency plan should include notifying local emergency 
managers and family members or others outside the immediate area that you have a 
shelter. This will allow emergency personnel to quickly free you if the exit from your 
shelter becomes blocked by debris. You should also prepare an emergency supply kit 
and either keep it in your shelter or be ready to bring it with you if you need to evacuate 
your house. Some of the items that the emergency supply kit should include are:

¥ an adequate supply of water for each person in your household

¥ non-perishable foods that do not have to be prepared or cooked 
(if these include canned goods, remember to bring a can opener)

¥ a Þrst-aid kit, including necessary prescription medicines

¥ tools and supplies:

- ßashlight (do not bring candles or anything that lights with a ßame)
- battery-operated radio  
- cellular phone or CB radio
- extra batteries   
- wrench (to turn off household gas and water)
- clothing and bedding
¥ special items:
- for babies- formula, diapers, bottles, powdered milk
- for adults- contact lenses and supplies, extra glasses

You can get more information about emergency planning from American Red Cross 
(ARC) and FEMA publications, which you can obtain free of charge by calling FEMA 
at 1-800-480-2520, or by writing to FEMA, P.O. Box 2012, Jessup, MD 20794-2012. 

These publications include the following:

Emergency Preparedness Checklist, FEMA L-154 (ARC 4471)

Food and Water in an Emergency, FEMA L-164 (ARC 5055)

Your Family Disaster Supplies Kit, FEMA L-189 (ARC 4463)

Preparing for Emergencies, A Checklist for People with Mobility Problems, FEMA L-
154 (ARC 4497)


These publications are also available on the World Wide Web at the FEMA web site -  
http://www.fema.gov - and at the American Red Cross web site - 
http://www.redcross.org


The Department of Homeland Security (DHS), has developed the READY.gov web 
site. You can Þnd emergency planning and preparation guidance for all types of 
potential hazards. To obtain a copy of Preparing Makes Sense. Get Ready Now, go to 
http://www.Ready.gov









Section II: 
Planning Your Shelter


Now that you better understand your risk from a tornado or hurricane, you can work 
with your builder/contractor to build a shelter to protect yourself and your family from 
these extreme windstorms. This section describes how extreme winds can damage a 
building, explains the basis of the shelter designs presented in this booklet, and shows 
where you can build a shelter in your house.



Building Damage

Extreme winds can cause several kinds of damage to a building. Figure II.1 shows how 
extreme winds affect a building and helps explain why these winds cause buildings to 
fail.

To understand what happens when extreme winds strike, you must Þrst understand that 
tornado and hurricane winds are not constant. Wind speeds, even in these extreme 
wind events, rapidly increase and decrease. An obstruction, such as a house, in the path 
of the wind causes the wind to change direction. This change in wind direction 
increases pressure on parts of the house. The combination of increased pressures and 
ßuctuating wind speeds creates stress on the house that frequently causes connections 
between building components to fail. For example, the roof or siding can be pulled off 
or the windows can be pushed in. 

Buildings that fail under the effects of extreme winds often appear to have exploded, 
giving rise to the misconception that the damage is caused by unequal wind pressures 
inside and outside the building. This misconception has led to the myth that, during an 
extreme wind event, the windows and doors in a building should be opened to equalize 
the pressure. In fact, opening a window or door allows wind to enter a building and 
increases the risk of building failure.

Damage can also be caused by ßying debris (referred to as windborne missiles). If 
wind speeds are high enough, missiles can be thrown at a building with enough force to 
penetrate windows, walls, or the roof. For example, an object such as a 2" x 4" wood 
stud weighing 15 pounds, when carried by a 250-mph wind, can have a horizontal 
speed of 100 mph and enough force to penetrate most common building materials used 
in houses today. Even a reinforced masonry wall will be penetrated unless it has been 
designed and constructed to resist debris impact during extreme winds. Because 
missiles can severely damage and even penetrate walls and roofs, they threaten not 
only buildings but the occupants as well.


Basis of Shelter Design

The purpose of a shelter is to provide a space where you and your family can survive a 
tornado or hurricane with little or no injury. In hurricane-prone areas, the shelter cannot 
be built where it can be ßooded during a hurricane. Your shelter should be readily 
accessible from all parts of your house, and it should be free of clutter. To protect the 
occupants during extreme windstorms, the shelter must be adequately anchored to the 
house foundation to resist overturning and uplift. The connections between all parts of 
the shelter must be strong enough to resist failure, and the walls, roof, and door must 
resist penetration by windborne missiles. 

Extensive testing by Texas Tech University and other wind engineering research 
facilities has shown that walls, ceilings, and doors commonly used in house 
construction cannot withstand the impact of missiles carried by extreme winds. The 
shelter designs in this booklet account for these Þndings by specifying building 
materials and combinations of building materials that will resist penetration by missiles 
in extreme winds.

The shelter designs, including both materials and connections, are based on wind 
speeds that are rarely exceeded in the United States. Therefore, a shelter built 
according to these designs is expected to withstand the forces imposed on it by extreme 
winds without failing. Those forces may cause cracks or other signs of stress in the 
materials or connections used in the shelter, and they may cause materials or 
connections to yield. However, the intent of the designs is not to produce a shelter that 
will always remain completely undamaged, but rather a shelter that will enable its 
occupants to survive an extreme windstorm with little or no injury.
It is very important to note that predicting the exact strength of tornadoes and hurricanes 
is impossible. That is another reason why the shelter designs in this booklet are based 
on extreme wind speeds and why the primary consideration is life safety.
Designing a building to resist damage from more than one natural hazard requires 
different, sometimes competing, approaches. For example, building a structure on an 
elevated foundation to raise it above expected ßood levels can increase its vulnerability 
to wind and seismic damage. These design approaches need to be thoroughly 
considered. In ßoodprone areas, careful attention should be given to the warning time, 
velocity, depth, and duration of ßoodwaters. These ßooding characteristics can have a 
signiÞcant bearing on the design and possibly even the viability of a shelter. Your local 
building ofÞcial or licensed professional engineer or architect can provide you with 
information about other natural hazards that affect your area and can recommend 
appropriate designs.


Shelter Size

The amount of ßoor area per person that your shelter must provide depends partly on 
the type of windstorm the shelter is intended to protect you from. Tornadoes are not 
long-lasting storms, so if you are relying on your shelter only for tornado protection, you 
will not need to stay in the shelter for a long time. As a result, comfort is not of great 
concern, and a shelter that provides about 5 square feet of ßoor area per person will be 
big enough.

When the shelter is intended to provide protection from storms such as hurricanes, 
which can last up to 12 hours, the comfort of the occupants should be considered. For 
this type of shelter, the recommended amount of ßoor area per person is about 10 
square feet. Necessities, such as water and toilet facilities, should be provided. The 
shelter designs in this booklet are based on a maximum ßoor area of 64 square feet and 
a maximum wall length of 8 feet. A shelter of that size used for hurricane protection 
can accommodate up to six people in reasonable comfort. If you plan to build a shelter 
with any wall longer than 8 feet, consult a licensed professional engineer or architect.



New vs. Existing Houses

The shelter designs in this booklet were developed primarily for use in new houses, but 
some can be used in existing houses. When a new house is being built, the 
builder/contractor can construct walls, foundations, and other parts of the house as 
required to accommodate the shelter. Modifying the walls or foundation of an existing 
house as necessary for the construction of a shelter is more difÞcult. As a result, some 
of the shelter designs in this booklet are not practical for existing houses. The following 
sections discuss this issue further.
In this booklet, the term "retroÞt" refers to the process of making changes to an existing 
house.



Foundation Types

Houses on the following types of foundations are suitable for the installation of a 
shelter:

¥ basement
¥ slab-on-grade
¥ crawlspace


A house on a basement foundation (see Figure II.2) is usually built on a foundation 
constructed of poured concrete or concrete masonry. Most concrete foundations are 
reinforced with steel bars or straps, but many concrete masonry foundation walls have 
no steel reinforcement. The framing for the ßoor above the basement is supported by 
the exterior foundation walls and sometimes by a center beam.
In a new or existing house with a basement, the shelter should be built in the basement. 
You can build the shelter as an entirely separate structure with its own walls, or you can 
use one or more of the basement walls as walls of the shelter. If you use the basement 
walls, they will have to be specially reinforced. Typical reinforcement techniques used 
in residential basement walls will not provide sufÞcient protection from missiles. In 
new construction, your builder/contractor can reinforce the walls near the shelter during 
the construction of your house. Reinforcing the basement walls of an existing house is 
not practical.

The likelihood of missiles entering the basement is lower than for above ground areas; 
however, there is a signiÞcant chance that missiles or falling debris will enter the 
basement through an opening left when a window, a door, or the Þrst ßoor above has 
been torn off by extreme wind. Therefore, your basement shelter must have its own 
reinforced ceiling; the basement ceiling (the Þrst ßoor above) cannot be used as the 
ceiling of the shelter.

The least expensive type of shelter that can be built in a basement is a lean-to shelter, 
which is built in the corner of the basement and uses two basement walls. The lean-to 
shelter uses the fewest materials, requires the least amount of labor, and can be built 
more quickly than other types of basement shelters.
In general, it is easier to add a basement shelter during the construction of a new house 
than to retroÞt the basement of an existing house. If you plan to add a basement shelter 
as a retroÞtting project, keep the following points in mind:

¥ You must be able to clear out an area of the basement large enough for the shelter.

¥ Unless the exterior basement walls contain steel reinforcement as shown on the 
design drawings provided with this booklet, these walls cannot be used as shelter walls 
since they are not reinforced to resist damage from missiles and uplift from extreme 
winds.

¥ Exterior basement walls that are used as shelter walls must not contain windows, 
doors, or other openings.

¥ The shelter must be built with its own ceiling, so that the occupants will be protected 
from missiles and falling debris.


A slab-on-grade house (see Figure II.3) is built on a concrete slab that is installed on 
compacted or natural soil. The concrete may be reinforced with steel that helps prevent 
cracking and bending. If you are building a new slab-on-grade house and want to install 
a concrete or concrete masonry shelter, your builder/contractor must make the slab 
thicker where the shelter will be built. The thickened slab will act as a footing beneath 
the walls of the shelter to provide structural support. It will also help anchor the shelter 
so that it will stay in place during an extreme wind event, even if the rest of the house is 
destroyed.

In an existing house, removing part of the slab and replacing it with a thickened section 
would involve extensive effort and disruption inside the house. Therefore, building a 
shelter with concrete or concrete masonry walls in an existing slab-on-grade house is 
generally not practical. You can, however, build a wood-frame shelter, because its 
walls are not as heavy and do not require the support of a thickened slab. A wood-
frame shelter can be created from an existing room, such as a bathroom or closet, or 
built as a new room in an open area in the house, such as a garage.

You can also build a shelter as an addition to the outside of a slab-on-grade house. This 
type of shelter must have not only proper footings, but also a watertight roof. Because a 
shelter built as an outside addition will be more susceptible to the impact of missiles, it 
should not be built of wood framing. Instead, it should be built of concrete or concrete 
masonry. Access to this type of shelter can be provided through an existing door or 
window in an exterior wall of the house.

In general, it is easier to add a shelter during the construction of a new slab-on-grade 
house than to retroÞt an existing slab-on-grade house. If you plan to add a shelter to a 
slab-on-grade house as a retroÞtting project, keep the following points in mind:

¥ The walls of the shelter must be completely separate from the structure of the house. 
Keeping the walls separate makes it possible for the shelter to remain standing even if 
portions of the house around it are destroyed by extreme winds.

¥ If you are creating your shelter by modifying a bathroom, closet, or other interior room 
with wood-frame walls, the existing walls, including sheathing on either the inside or 
outside of the walls, such as drywall or plaster, must be removed and replaced with 
walls and a ceiling resistant to the impact of windborne missiles and other effects of 
extreme winds.

¥ If you intend to build a shelter with concrete or concrete masonry walls, a section of 
your existing slab ßoor will have to be removed and replaced with a thicker slab. As 
noted above, this is usually not practical in an existing house.


A house built on a crawlspace (see Figure II.4) usually has a ßoor constructed of wood 
framing. Along its perimeter, the ßoor is supported by the exterior foundation walls. 
The interior part of the ßoor is supported by beams that rest on a foundation wall or 
individual piers. Crawlspace foundation walls may be concrete, but are usually 
constructed of concrete masonry. Crawlspace foundation walls are often unreinforced 
and therefore provide little resistance to the stresses caused by extreme winds.

Building a shelter inside a house on a crawlspace foundation is more difÞcult than 
building a shelter inside a house on a basement or slab-on-grade foundation. The main 
reason is that the entire shelter, including its ßoor, must be separate from the framing of 
the house. As shown in Figure II.4, a shelter built inside the house cannot use the ßoor 
of the house. The shelter must have a separate concrete slab ßoor installed on top of 
earth Þll and must be supported by concrete or concrete masonry foundation walls. An 
alternative approach, which may be more economical, is to build an exterior shelter on 
a slab-on-grade adjacent to an outside wall of the house and provide access through a 
door installed in that wall.

Ventilation in the area below the ßoor of the house is also an important issue. The 
wood-framed ßoor of a house on a crawlspace foundation is typically held 18 to 30 
inches above the ground by the foundation walls. The space below the ßoor is designed 
to allow air to ßow through so that the ßoor framing will not become too damp. It is 
important that the installation of the shelter not block this air ßow.
In general, it is much easier to build a shelter inside a new crawlspace house than in an 
existing crawlspace house. If you plan to add a shelter to an existing crawlspace house 
as a retroÞtting project, keep the following in mind:

¥ The shelter must have a separate foundation. Building the foundation inside the house 
would require cutting out a section of the existing ßoor and installing new foundation 
members, Þll dirt, and a new slab - a complicated and expensive operation that is often 
not practical.

¥ A more practical and more economical approach would be to build an exterior 
shelter, made of concrete or concrete masonry, on a slab-on-grade foundation adjacent 
to an outside wall of the house, as described above.




Shelter Location
There are several possible locations in your house for a shelter. Perhaps the most 
convenient and safest is below ground level, in your basement. If your house does not 
have a basement, you can install an in-ground shelter beneath a concrete slab-on-grade 
foundation or a concrete garage ßoor. Basement shelters and in-ground shelters provide 
the highest level of protection against missiles and falling debris.
Another alternative shelter location is an interior room on the Þrst ßoor of the house. 
Researchers, emergency response personnel, and people cleaning up after a tornado 
have often found an interior room of a house still standing when all other above ground 
parts of the house have been destroyed. Closets, bathrooms, and small storage rooms 
offer the advantage of having a function other than providing occasional storm 
protection. Typically, these rooms have only one door and no windows, which makes 
them well-suited for conversion to a shelter. Bathrooms have the added advantage of 
including a water supply and toilet.

Regardless of where in your house you build your shelter, the walls and ceiling of the 
shelter must be built so that they will protect you from missiles and falling debris, and 
so that they will remain standing if your house is severely damaged by extreme winds. 
If sections of your house walls are used as shelter walls, those sections must be 
separated from the structure of the house. This is true regardless of whether you use 
interior or exterior walls of the house.

Figures II.5 through II.7 are typical ßoor plans on which possible locations for shelters 
are shown with yellow highlighting. These are not ßoor plans developed speciÞcally for 
houses with shelters. They show how shelters can be added without changes to the 
layout of rooms.


Floor Plan 1: basement

Possible shelter locations in a basement include the following:

¥ in a corner of the basement, preferably where the basement walls
 are below the level 
of the ground

¥ in a bathroom, closet, or other interior room in the basement

¥ in a freestanding addition to the basement


A space that is to be used for a shelter must be kept free of clutter so that the shelter 
can be quickly and easily entered and so that the shelter occupants will not be injured 
by falling objects. For this reason, a bathroom is often a better choice for a shelter than 
a closet or other space used for storage. Remember, if the basement is below the level 
of storm surge or the level of ßooding from any other source, it is not a suitable location 
for a shelter. In this situation, a possible alternative would be to build an exterior shelter, 
adjacent to your house, on a slab-on-grade above the ßood level.


Floor Plan 2:  house on a slab-on-grade or crawlspace foundation

Possible shelter locations in a house on a slab-on-grade or crawlspace foundation 
include the following spaces on the Þrst ßoor:

¥ bathroom
¥ closet
¥ storage room
¥ laundry room (provided the load-bearing wall between it and the garage, as shown in 
Figure II.6, can be properly separated from the structure of the house)

¥ corner of the garage
Regardless of where the shelter is built, it must be equipped with a door that will resist 
the impact of missiles. Remember, if the Þrst ßoor of the house is below the level of 
storm surge or the level of ßooding from any other source, it is not a suitable location 
for a shelter. In this situation, a possible alternative would be to build an 
exterior shelter on a slab-on-grade 
elevated on Þll above the ßood 
level.



Floor Plan 3: house on a slab-on-grade foundation

Possible locations for an in-ground shelter include the following:

¥ below the slab in a closet or storage room

¥ below the ßoor of the garage, in an area where cars will not be parked


Because of the difÞculty of installing an in-ground shelter in an existing house, this type 
of shelter is practical only for new construction. Remember, if the Þrst ßoor of the 
house is below the level of storm surge or the level of ßooding from any other source, it 
is not a suitable location for a shelter. In this situation, a possible alternative would be to 
build an exterior shelter on a slab-on-grade elevated on Þll above the ßood level.
Tables II.1 and II.2 will help you decide what type of shelter is appropriate for your 
circumstances. Table II.1 applies to the construction of shelters in new houses. Table 
II.2 applies to retroÞt situations, in which a shelter is being added to an existing house.



Construction Materials

The materials your builder/contractor will need to build your shelter should be available 
from building material suppliers in your community. These materials have been 
carefully selected for their strength, durability, and/or ability to be readily combined in 
ways that enable them to withstand the forces of extreme winds and the impact of 
windborne missiles. Your builder/contractor should not substitute any other material for 
those speciÞed in the designs.

One of the most vulnerable parts of your shelter is the door. The materials speciÞed for 
doors in the shelter designs in this booklet were tested by the Wind Engineering 
Research Center at Texas Tech University for their ability to carry wind loads and 
prevent penetration by missiles. The installation of the door is as important as the 
materials used in its construction. Please conÞrm with your builder/contractor that the 
door to your shelter can be installed the way it is shown in the designs included with this 
booklet.

A complete list of the shelter construction materials, with their expected strengths or 
properties, is included in the shelter designs provided in this booklet. Your 
builder/contractor should use it when buying the materials for your shelter.



Shelter Cost

The cost of your shelter will vary according to the following:

¥ the size of the shelter

¥ the location of the shelter

¥ the number of exterior house walls used in the construction of the shelter
¥ the type of door used

¥ the type of foundation on which your house is bui
lt
¥ your location within the United States (because of regional variations in labor and 
material costs) 

¥ whether you are building a shelter into a new house or retroÞtting an existing house


Table II.3 shows the average costs for building three types of shelters- lean-to, 
aboveground (AG), and in-ground - in new houses on basement, slab-on-grade, and 
crawlspace foundations according to the design plans in this booklet. These costs are 
for shelters with a ßoor area of 8 feet by 8 feet.
The cost of retroÞtting an existing house to add a shelter will vary with the size of the 
house and its construction type. In general, shelter costs for existing houses will be 
approximately 20 percent higher than those shown in Table II.3.






NOTE
The shelter designs in this booklet are applicable for any on-site construction. However, 
in a modular house, the shelter location would be limited to the basement or the below-
ground module. A modular house is a house constructed of modular units that have 
been built elsewhere, brought to the site, and installed on a permanent foundation



WARNING

You should not install a shelter in a house supported by piles, piers, or columns. With 
building connectors commercially available, there is no economical way to separate 
the shelter from the ßoor framing and ensure that the shelter will withstand the forces of 
extreme winds.
You may be tempted to build a shelter under a house on a pile, pier, or column 
foundation. However, if the house is in a storm surge area or other ßood hazard area, 
the area under the house would be below the ßood level. A shelter built in that area 
would trap its occupants in rising floodwaters. See the warning on page 5 for more 
information






 

Section III: 
Building Your Shelter


Your builder/contractor can use the design drawings in this booklet to build a shelter for 
any of the wind zones shown on the map in Figure I.2. The design drawings provided 
include the details for building Þve types of shelters: concrete, concrete masonry, 
wood-frame, lean-to, and in-ground. Each of these alternatives is expected to perform 
equally well in resisting material fatigue and connection failures caused by extreme 
winds.

The materials and connections were chosen for their "ultimate strength," which means 
that the materials are expected to resist the loads imposed on them until they or the 
connections between them fail. The forces of extreme winds may cause cracks or 
other signs of stress in the materials or connections, and they may cause materials or 
connections to yield. However, the intent of the designs is not to produce a shelter that 
will always remain completely undamaged, but rather a shelter that will enable its 
occupants to survive an extreme windstorm with little or no injury. The shelter itself 
may need to be extensively repaired or completely replaced after an extreme wind 
event.

The shelter size and materials speciÞed in the drawings are based on principles and 
practices used by structural engineering professionals and the results of extensive 
testing for effects of missile impact. Before increasing the shelter size or using material 
types, sizes, or spacings other than those speciÞed in the drawings, review the changes 
with a licensed professional structural engineer.

The information in this section includes the following:

¥ design drawings and details for shelters in basements, above the ground, and in the 
ground

¥ designs for both slab-on-grade and crawlspace foundations

¥ general design notes and fastener and hardware schedules


¥ materials lists with quantities and speciÞcations


The Wind Engineering Research Center at Texas Tech University has been involved in 
shelter design for many years. If you or your builder/contractor have questions about 
the design drawings in this booklet, call the Wind Engineering Research Center at (888) 
946-3287, ext. 336 for technical guidance.

The following is an index of the design drawings provided in this booklet:

Sheet No. Drawing No.* Title 

 1 of 16 1 Index Sheet 
 2 of 16 2 General Notes 
 3 of 16 IG-1 In-Ground Shelter - Sections and Details 
 4 of 16 B-1 Basement Lean-To 
 5 of 16 B-2 Basement Shelter - Corner Location 
 6 of 16 AG-1 CMU/Concrete Alternative Plans 
 7 of 16 AG-2 CMU/Concrete Wall Sections 
 8 of 16 AG-3 CMU/Concrete Sections - Ceiling Alternatives 
 9 of 16 AG-4 Wood-Frame Shelter Plan - Plywood Sheathing w/ CMU InÞll 
10 of 16 AG-5 Wood-Frame Shelter Plan - Plywood and Steel Wall Sheathing 
11 of 16 AG-6 Wood-Frame Shelter - Foundation Sections
12 of 16 AG-7 Insulating Concrete Form - Plans
13 of 16 AG-8 Insulating Concrete Form- Sections
14 of 16 14 Misc. Details
15 and 16 of 16 15 and 16 Materials Lists 

* IG = In-Ground,  B = Basement,  AG = Aboveground



How To Use the Drawings

¥ Drawings shall not be scaled to determine dimensions.

¥ If there is a conßict between a dimension shown on the drawings and a scaled 
dimension, the dimension shown on the drawing shall govern.

¥ If there is a conßict between the drawings and local codes, the local codes shall 
govern.

¥ If there is a conßict among the general notes, speciÞcations, and plans, the order of 
precedence is notes, then speciÞcations, then plans.