The forces upon a collector and roo

The forces upon a collector and roof are the major consideration when designing a rack or selecting mounting hardware. These forces a categorized as dead loads, live loads, and environmental loads. Dead loads result from the weight of the collector, the mounting hardware, and the collector fluid-and remain constant. For SWH systems that use glazed flat-plate or evacuated-tube collectors, the collector dead load is approximately 3 to 5 pounds per square foot(psf). For comparison, a layer of shingles has a dead load of 2 to 3 psf. he exact empty and filled weights of a particular collector can be obtained from the manufacturer's specification sheets. Integral collector storage(ICS) units and thermosyphon systems contain tanks and may have dead loads that range from 25 to 70 psf Live loads are intermittent, resulting from movable objects The weights of the staged equipment and of solar installers working on a roof would be considered live loads. These loads typically don't affect rack design, but the roof itself must be able to support live loads Environmental loads come from rain, snow, earthquakes and wind. Rain is rarely considered when designing the mounting for a solar array unless the design causes pooling on the roof. It is best practice to avoid such a situation by orienting the attachments to the roof in a manner that permits normal drainage of the roof surface Typical snow loads in the United States range from zero in areas such as Florida and Southern California to 100 psf in northern Maine to up to 400 psf in some locations in Alaska. Drifting and sliding snow can increase these loads
significantly. Snow loads for collector racks are affected by local siting-whether they are in an exposed area where wind will readily blow snow off, or they are in a sheltered area where the snow is unlikely to be blown away Due to their filled weight, ICS and thermosyphon systems may be subjected to significant earthquake loads Consideration of earthquakes is specific to portions of California, as well as Hawaii, Puerto Rico, and the U.S. Virgin Islands. Evaluating the effects of these loads is complex and should involve professional engineering Wind loads are a critical consideration for tilted racks. The greater angle a collector is from the plane it is mounted on, the more impact wind loads will have. The magnitude of wind loads depends upon Wind speeds at the particular location The height at which the collector is mounted. A collector mounted on a 30-foot-high roof, for example, will experience greater wind loads than one mounted on a lower roof The collector exposure. Coastal homes that are unsheltered, for example, will have much greater wind loads than homes sheltered by large buildings or trees Wind-loading effects are exponentially related to the wind speed. A site with twice the wind speed of another will be subject to four times the wind force. Maps are available to assist designers with determining wind speed. In some cases, local authorities having jurisdiction will specify the design" ind speed
Distributed versus concentrated loads. Many roof loads are considered distributed loads, which means they are spread out evenly over an area-like the roof sheathing, underlayment and roofing material. Wind and snow loads on the roof surface are also distributed loads. But when the wind or snow load is on the collector, it is exerted on the feet, becoming a concentrated load, which is applied to points on the roof structure. Concentrated loads for flush-mounted collectors tend to have minimal impact on the stresses in the roof structure. When collectors are installed on tilt racks, the geometry of a tilt rack amplifies the impacts of the wind. The design of the mounting rack will have a significant effect on how large the concentrated loads will be on the roof structure.
Ground Mounted SWH Systems Likely, the best solar window at your site will determine whether your solar water heating(SWH) system is roof-mounted or ground mounted. Both have their advantages and disadvantages Since the ground-mount is independent of the roof, any concerns associated with the strength of the roof for supporting solar collectors are eliminated. Using a ground-mounted array also minimizes the safety risks associated with installing equipment on an elevated surface. Tilt racks are commonly used in ground mounted systems and provide the owner with an opportunity to install the collectors at an angle that best suits the application However, ground-mounted systems require their own foundation and are usually more expensive than roof-mounted SWH systems. Besides cost, there are other challenges associated with ground-mounted arrays. The type of soil in an area can have a huge impact on the stability of a new foundation. The presence of rock ledge may require drilling and pins to secure the foundation and clay may cause settling that could affect the integrity of the collector array. Additionally, ground-mounted arrays typically require burying pipe and can significantly increase the amount of piping needed between the collector array and the storage tank. This not only adds costs but also can affect performance by increasing heat loss in the system and potentially requiring more pumping power.
Rack Design Racks are designed to transfer dead and environmental loads from the collectors to the roof structure. Hardware secures the collectors to the rack, the rack is attached to the building surface(usually the roof and the structure then carries the loads to the ground. SWH mounting kits are usually available from the collector manufacturer to match the collectors' frame. Most mounting kits use clamps that are inserted into frame extrusions, and proprietary mounting hardware. This is in contrast to most PV racks, which can be used with most modules. Two types of tilt racks are common strut-type aluminum racks for flat-plate collectors and stainless-steel racks for evacuated-tube collectors. ICS units may also be installed o tilt racks, but these collectors are less prevalent in the U.S than flat-plate and evacuated-tube collectors. Installing collectors in a landscape position can improve the aesthetics of the installation and reduce the wind loads the roof
Tilt or Parallel? For aesthetics, it is often preferable to mount collectors at the same slope as the roof Parallel-mounted arrays are less conspicuous and also minimize the effects of wind on the collector array. But in systems where parallel mounting will dramatically impact system performance-for example when the roof pitch is too shallow, placing the collector at risk of summertime overheating and wintertime underperformance-tilt racks may be used. A tilt rack elevates the upper portion of the collector to increase the array's mounting angle. For further discussion about the impact of the collector tilt on system performance see"Site Assessment for Solar Water Heating Systems in HP159(homepower.com/159.64)
Aluminum for flat-plate collectors. Several manufacturers offer a tilt rack that uses two struts one supports the upper portion of the collector, while the other supports the bottom portion. The upper strut is connected to legs attached to feet that are secured to the roof structure. The lower rail is attached directly to mounting feet without legs. The distance between the rails depends upon the environmental loads and the strength of the collector frame. Loads can cause bending stresses, which also are affected by beefiness of the collector frame. Lighter, shallower frames will have more deflection(i.e., will bend more) and require more support than deeper frames. Longer cantilevers will increase the stresses in the collector frame, as will a large spacing between the rails. The allowable cantilever collector is less than the allowable span between the rails. For example SunEarth specifies a maximum cantilevered length that is 20% When the roof orientation is less than ideal, tilt racks can often be rotated 90° to allow for a wall-mounted array
This aluminum tilt-up rack for flat-plate collectors(by SunEarth) makes the most of a shallow roof pitch. of the length of the collector while allowing the rails to be spaced at roughly 75% of the collector length. Stainless steel for evacuated-tube collectors In contrast to flat-plate collectors, which can use the structure of the collector frame for bracing and support, evacuated-tube collectors rely strictly on the rack for structural support. Since stainless steel is stronger than aluminum, the thickness and size of an evacuated-tube rack tend to be thinner and smaller than those for a flat-plate collector. Racks for evacuated tubes require significantly more bracing-the manifold could easily be pushed sideways since the collector itself lacks the rigidity of a flat-plate collector. Diagonal bracing is required for evacuated-tube tilt racks.
An evacuated-tube collector is secured to the rack by clamping the manifold and the tube's mounting rail to a frame, which has two or three rails that run parallel to the tubes. The collector is tilted by using legs bolted to the mounting rails and attached to the roof via a foot or to another stainless steel section that connects to the bottom end of the mounting rail to form a triangle Evacuated-tube collectors often need cross-bracing, seen here through and behind the tubes.
Sealing Roof Attachments With the recent explosion of residential grid-tied PV systems numerous flashing products have been introduced to help waterproof roof attachment points. Many of these products are easy to integrate with parallel-mounted solar collectors However, using these products with tilt racks proves to be a greater challenge. Most mounting feet on tilt racks require two lag screws to resist the withdrawal forces that can occur at the rear foot. Though there are a number of mechanical flashing products on the market that utilize two lag screws, only a few integrate with selected tilt racks in the SWH industry. H