Hot Flue Discharge | Dayton 3VH34, 3VH37, 5VD57, 3.00E+134, 3.00E+132

Ventilation

! WARNING

Improper ventilaton may result in

Eproperty damamge, health problems,

Ncarbon monoxide poisoning, injury or

Gdeath.

I It is required that the upper levels of the space to be S heated are properly ventilated to supply combustion H air to the heaters and to sufficiently dilute the products

of combustion. It is also required that the flue discharge area is kept clear of gas piping and electrical wiring (see Figure 2.6).

This infra-red heater must be vented in accordance with national, state, provincial and local codes and the guidelines in this manual. In the United Sates refer to the latest edition of ANSI Z223.1 (NFPA 54) and in Canada refer to the latest edition of the CAN/CGA B149.2 Standard.

Provisions must also be made to provide sufficient fresh air intake area and exhaust air outlet area. For proper ventilation, a positive air displacement of 4.0 CFM per 1000 BTU/H of natural gas consumed must be provided. If propane is used, a positive air displacement of 4.5 CFM per 1000 BTU/H of propane gas consumed must be provided.

Where insufficient air movement exists, induced air displacement is required. A balanced system is essential to avoid negative building pressure which causes excessive infiltration, unfavorable drafts and affects combustion efficiency.

Air displacement may be accomplished by either gravity or mechanical means. Mechanical exhausters are preferred and typically mounted at high points on the roof where stagnant air accumulates inside the building. For a flat roof, considerations of prevailing winds, high and low pressure areas, and distribution of air movement must be taken into consideration when locating exhausters.

Dayton® High Intensity Heaters

Dayton Installation, Operation, Maintenance and Parts Manual

3E132 thru 3E134, 3E460 thru 3E462, 5VD57 thru 5VD66, 3VH34 thru 3VH37

! CAUTION

Ventilate enclosed spaces and buildings according to national, state, provincial and local codes. Failure to provide adequate ventilation may result in

equipment malfunctions, condensation and other air quality issues.

Figure 2.6 Hot Flue Discharge

Flue discharge	Manifold/
Flue discharge	Control End
Important! Do not	Down
install gas piping or
electrical wiring
above the flue
discharge area!

20˚ - 35˚

SIDE VIEW

Best air distribution is accomplished by using a number of small exhausters versus one large exhauster. Provide a minimum of one square inch of inlet area per 1000 BTU/H for combustion air supply. Inlet opening in the building should be well distributed (see Figure 2.1) high in the sidewalls and should direct incoming air upward to dilute products of combustion while preventing drafts at lower levels. Inlets are typically 1 to 3 sq. ft.

Local codes may require that mechanical exhaust systems be interlocked with heaters to enable both to function simultaneously (see page 17, Figure 2.7) or allow control of exhausters with a ceiling mounted humidistat.

3E460, 3E462, 3.00E+132, 3.00E+134, 5VD57 specifications

Dayton 3.00E+134, 5VD57, 3E462, 3E460, 3.00E+132 is a distinctive model within the Dayton series known for its advanced performance in various applications. This line of products is designed to meet the demands of both commercial and industrial sectors, showcasing a blend of efficiency, durability, and innovative technology.

One of the main features of the Dayton 3.00E+134 series is its powerful motor capabilities. The models utilize high-efficiency motors that ensure optimal energy consumption while providing robust operational performance. This not only helps to reduce utility costs but also plays a crucial role in minimizing the environmental footprint.

The technology behind Dayton products often incorporates advanced electronic controls that allow for precise adjustments and operations. This feature is particularly beneficial in environments where maintaining specific conditions is essential, such as HVAC systems and industrial processes. The electronic controls provide users with greater flexibility and range in performance settings, accommodating various operational requirements.

In terms of construction, the Dayton 3.00E+134 models are built with high-quality materials that ensure long-lasting durability. This is critical in settings where equipment is subjected to heavy usage or challenging environmental conditions. The robust design and protective coatings prevent corrosion and wear, ensuring that the equipment maintains its functionality over extended periods.

Another characteristic worth noting is the versatile range of applications for these models. They can be used in air movement, ventilation, heating, and cooling systems, making them highly valued in multiple sectors, such as manufacturing, healthcare, and commercial buildings. Their adaptability means they can seamlessly integrate into existing systems without requiring extensive modifications.

The ease of installation and maintenance is also a highlight of the Dayton 3.00E+134 series. The design facilitates quick assembly and access for servicing, saving valuable time and labor costs. Users appreciate the convenience offered, allowing them to focus on core business operations without prolonged downtime.

Furthermore, these models comply with industry standards and regulations, ensuring safety and reliability in operation. Overall, the Dayton 3.00E+134, 5VD57, 3E462, 3E460, 3.00E+132 series represents a pinnacle in engineering excellence, delivering exceptional performance across various applications while prioritizing energy efficiency and user-friendly functionality.