Storage Buildings

It almost appears that almost every, home and garage is bursting at the seams. Surplus or unneeded equipment, furniture or other belongings clutter closets, attics and garages. But, the option of monthly storage fees does seem like a hefty price to pay just to hold on to the things you have.

Self-storage buildings are an easy way to put your money in someone else's pocket. Holiday decorations, childhood keepsakes and files all need to be retained for different reasons, but the cost of storage is a burden. Owning your own storage buildings is one way to lessen the expense of personal storage with a one-time quality investment.

The exciting thing about steel frame storage buildings is that you only buy them once. Mini storage is not as friendly you pay and pay, but you never own anything but the contents you placed in them. You may think that you don't need something as permanent as owning a personal storage building. But think about it - when are you going to let go of the things you have decided to save?

Structural Design

We design and manufacture pre-engineered steel buildings, and offer you a number of advantages over conventional construction techniques. Steel buildings are inexpensive and incredibly tough. Our bolt-together design is assembled quickly without any specialized skills. Each rigid frame is comprised of two or more columns supporting a rafter across the width of the building. In most steel buildings, endwall bearing frames support one-half the load of a rigid "main" frame. In most situations, we utilize the more economical "bearing" end frames. Adding an expandable endwall or rigid frame is only a click away. Unlike any of our competitors, we allow you to choose the endwall condition of your building. Depending on design considerations, our endwall rafters and columns may be either hot rolled or cold-formed.

The space between the rigid frames of a steel building is referred to as a "bay."- an 80' long building has been divided into four 20' bays by spacing the frames 20' apart (4 x 20' = 80'). This configuration is described as "four bays at 20." A 100' building could be configured with four bays at 25 (4x 25' = 100')

Endwall bay spacing is usually determined by the building width. You can add one or more framed openings to most buildings. Endwall bay spacing can usually changed to accommodate your needs without changing the price.

ABOUT US

COMMITMENT - Our Company's vision is "to maintain a leading-edge in the design, engineering, fabrication and delivery of the highest quality steel buildings in the industry." We are deeply committed to providing you with this service as a means of achieving our vision.

VALUE - Low initial cost does not always provide the best value. It is just a small part of the picture. The values inherent in our designs assist in the ease of construction of the project but more importantly we provide a well-documented system that is easy to maintain. Much of the value we bring lies in the details. There is a true ART to engineering and design that provides added value to the Owner.

EXPERIENCE - With over 8 years in the manufacturing business and key staff members with many more years in engineering, we have the requisite experience. Major hardware and accessory suppliers have reviewed our capabilities and recognize us as leaders in our field. Many of our projects involve very difficult project constraints. Dealing with these issues and tight project schedules is the trademark of our success.

PROJECT METHODOLOGY - The success of a project lies in the talent of the design team and in the execution of the project. We first provide a strong project team, backed up with a well-defined and proven project execution methodology. Our project methodology has evolved over the years as we have executed numerous projects. It begins with our proposal document and extends through project documents, design sequence, system testing, acceptance documents and to the final delivery of our building system. The key to our methodology is communication. We strongly believe in defining what we are providing and expanding this initial definition as the project continues.

QUALITY - In engineering, quality relates to the designs we produce and the timing in project execution. Our goal for design is to provide a superior level of detail in documentation. We strive for uniformity of design, providing details often left out by others and keeping systems simple. The key to being on time is project execution. First, a well-defined project methodology is needed to set the planning framework. Second, understanding of the Owner's needs is paramount. Finally, our years of experience in the execution of critical projects have given us an essential edge over our competitors. Key members of our staff have up to thirty-five years of experience in project engineering and execution.

Calculated Thermal Values

Basically it is the reciprocal of the calculated U-Value. By definition it is the summation of all the R-Values for each of the building's components. This method of calculation does not consider the thermal short circuit effect of structural members, fastener population or the compression of the insulation at its structural members. It should also be noted that this type of calculation often indicates heat loss values for building envelopes that are lower than those actually found in the finished structure.

Heat Transfer

Effectively controlling temperature in a steel building requires insulation to be present along exterior walls and roof. When a temperature differential is present in an enclosed steel building, heat will work from warmer areas to colder areas until the temperature in the building has stabilized. At the point of thermal stabilization, the cooler (and heavier) air will be present at lower elevations and warmer air will be present at the roofline. The function of insulation is to help stabilize air temperature at more desirable levels. When it is hot outside, preventing heat from transferring into the building is the goal, and of course in the winter we want heat to remain inside.

Heat transfer occurs in three ways:

Conduction : Occurs in a solid or liquid when heat from one object is transferred by touch to another object. An example of this occurs when a pot on a stove will heat up by conductive heat transfer from an electric coil.

Convection : Occurs with the physical movement of air. There are two types of convectional heat movement. The first is natural, where hot air rises displacing the cold air and moving it down. The second type is forced or mechanical convection. This occurs when an object, like a fan, physically moves or "forces" the air to move.

Radiation : Occurs when an object is warmer or hotter than the air around it. For example, the sun, which is hotter than everything around it, radiates heat waves that travel through the air and is either absorbed by or reflected by the surface it comes in contact with.