AIR for Combustion and Ventilation

AIR FOR COMBUSTION AND VENTILATION

Providing Adequate Ventilation

Determining Fresh-Air Flow For Heater Location

WARNING: This heater shall not be installed in a confined space or unusually tight construction un- less provisions are provided for adequate combus- tion and ventilation air. Read the following instruc- tions to insure proper fresh air for this and other fuel- burning appliances in your home.

Today’s homes are built more energy efficient than ever. New materi- als, increased insulation, and new construction methods help reduce heat loss in homes. Home owners weather strip and caulk around windows and doors to keep the cold air out and the warm air in. During heating months, home owners want their homes as airtight as possible.

While it is good to make your home energy efficient, your home needs to breathe. Fresh air must enter your home. All fuel-burning appliances need fresh air for proper combustion and ventilation.

Exhaust fans, fireplaces, clothes dryers, and fuel burning appliances draw air from the house to operate. You must provide adequate fresh air for these appliances. This will insure proper venting of vented fuel-burning appliances.

PROVIDING ADEQUATE VENTILATION

The following are excerpts from National Fuel Gas Code, ANSI Z223.1/NFPA 54, Section 5.3, Air for Combustion and Ventilation.

All spaces in homes fall into one of the three following ventilation classifications:

1.Unusually Tight Construction

2.Unconfined Space

3.Confined Space

The information on pages 4 and 5 will help you classify your space and provide adequate ventilation.

Unusually Tight Construction

The air that leaks around doors and windows may provide enough fresh air for combustion and ventilation. However, in buildings of unusually tight construction, you must provide additional fresh air.

Unusually tight construction is defined as construction where:

a.walls and ceilings exposed to the outside atmosphere have a continuous water vapor retarder with a rating of one perm (6 x 10-11kg per pa-sec-m2) or less with open- ings gasketed or sealed and

b.weather stripping has been added on openable windows and doors and

c.caulking or sealants are applied to areas such as joints around window and door frames, between sole plates and floors, between wall-ceiling joints, between wall pan- els, at penetrations for plumbing, electrical, and gas lines, and at other openings.

If your home meets all of the three criteria above, you must provide additional fresh air. See Ventilation Air From Out- doors, page 5.

If your home does not meet all of the three criteria above, proceed to Determining Fresh-Air Flow For Heater Location.

Confined and Unconfined Space

The National Fuel Gas Code, ANSI Z223.1/NFPA 54 defines a confined space as a space whose volume is less than 50 cubic feet per 1,000 Btu per hour (4.8 m3 per kw) of the aggregate input rating of all appliances installed in that space and an unconfined space as a space whose volume is not less than 50 cubic feet per 1,000 Btu per hour (4.8 m3 per kw) of the aggregate input rating of all appliances installed in that space. Rooms communicating directly with the space in which the appliances are installed*, through openings not furnished with doors, are considered a part of the unconfined space.

*Adjoining rooms are communicating only if there are doorless passageways or ventilation grills between them.

DETERMINING FRESH-AIR FLOW FOR HEATER LOCATION

Determining if You Have a Confined or Unconfined Space

Use this work sheet to determine if you have a confined or unconfined space.

Space: Includes the room in which you will install heater plus any adjoining rooms with doorless passageways or ventilation grills between the rooms.

1.Determine the volume of the space (length x width x height). Length x Width x Height = ___________ cu. ft. (volume of space)

Example: Space size 22 ft. (length) x 18 ft. (width) x 8 ft. (ceiling height) = 3168 cu. ft. (volume of space)

If additional ventilation to adjoining room is supplied with grills or open- ings, add the volume of these rooms to the total volume of the space.

2.Multiply the space volume by 20 to determine the maximum Btu/Hr the space can support.

__________ (volume of space) x 20 = (Maximum Btu/Hr the space

can support)

Example: 2560 cu. ft. (volume of space) x 20 = 51,200 (maximum Btu/Hr the space can support)

For morevisit www..com

107902-01D

GWN10T, GWP10T, GWRN10, GWN6, GWP6 specifications

Desa GWN10, GWP10, GWRP10, GWP6, and GWN6 are innovative products designed to meet diverse demands in various sectors. Each model brings unique features and characteristics, tailored for specific applications in the world of technology and daily use.

Desa GWN10 is recognized for its robust design and energy efficiency. It employs advanced wireless communication technology, enabling seamless integration with smart home systems. The GWN10 stands out with its high performance in terms of connectivity range and reliability. It offers users the convenience of remote monitoring and control, making it ideal for residential and commercial use, especially in areas that require a secure and efficient energy solution.

GWP10, on the other hand, is engineered for flexibility and versatility. Its modular design allows users to configure the system according to their specific needs. The GWP10 utilizes cutting-edge battery technology, providing longer usage times and faster charging capabilities. With its user-friendly interface and cloud connectivity, users can easily track energy consumption and optimize settings for enhanced performance.

The GWRP10 is a game-changer in renewable energy applications. Equipped with advanced solar integration technologies, it can harness solar power effectively, making it an eco-friendly choice. The GWRP10 features intelligent energy management systems that optimize power distribution, ensuring that energy is used efficiently. This model is perfect for users looking to reduce their carbon footprint while enjoying reliable power supply.

GWP6, a compact powerhouse, offers exceptional performance in a smaller footprint. Its lightweight construction and easy installation make it suitable for urban environments where space is a premium. The GWP6 leverages latest communication standards, such as IoT connectivity, providing real-time data insights for users. This makes it ideal for mobile applications and temporary installations.

Finally, the GWN6 emphasizes portability and ease of use. With its rugged design, it is perfect for outdoor activities and off-grid solutions. The GWN6 includes battery backup options, ensuring uninterrupted power during outdoor adventures. Its durable build and waterproof features make it reliable for challenging environments.

Together, these models showcase Desa’s commitment to innovation, sustainability, and user-centric design. Whether for energy management, renewable energy integration, or portable power, Desa GWN10, GWP10, GWRP10, GWP6, and GWN6 provide advanced solutions for contemporary needs. Their groundbreaking technologies and features are setting new standards in their respective categories, making them valuable assets for both everyday consumers and businesses alike.

Desa GWN10, GWRN10, GWN6, GWRP10 AIR for Combustion and Ventilation, Providing Adequate Ventilation

Models: GWN10T GWP10T GWRN10 GWN6 GWP6 GWRP10 GWP10 GWN10