OWNER’S MANUAL

FREESTANDING FIREPLACE ASSEMBLY

Continued

INSTALLING OPTIONAL BLOWER ACCESSORY

NOTICE: If installing blower in an existing fireplace with gas con- nections, shut off gas supply and disconnect heater from gas sup- ply. Contact a qualified service person to do this.

Attaching Thermal Switch to DA3610T Thermostatically Controlled Blower

When installing the DA3610T thermostati- cally controlled blower accessory, you must first secure the thermal switch to the blower.

1.

Remove the two hex head screws on the

 

blower assembly as shown in Figure 15.

2.

Place the green wire between the bot-

 

tom hole on the thermal switch bracket

 

and the bottom hole on the blower as-

 

sembly. Insert one of the hex screws

 

into all three pieces and tighten.

3.

Insert the top screw through the ther-

 

mal switch bracket and into the blower

 

assembly. Tighten screw.

4.

Connect the blue wire on the blower

 

assembly to the right side of the ther-

Installing GA3700/DA3610T Blowers

1.Align the holes in the top mounting tabs of blower with holes in wall of rear cover (see Figure 16). Using the 4 screws provided, mount blower and tighten screws securely.

Note: For DA3610T, make sure the ther- mal switch has been properly installed to fit against the back of the firebox.

2.Make sure all wire connections to ter- minals on blower motor (and thermal switch where applicable) are securely attached and that the screw retaining the green ground wire is tight.

3.Place speed control on left inside of rear cover and push the plastic control shaft through opening (see Figure 16).

4.While supporting speed control, secure control shaft with lock nut by pushing and turning lock nut with pliers clockwise until tight against the side of rear cover. Place control knob provided onto shaft (see Figure 16).

5.Plug in blower power cord.

6.Check to make sure that the power cord is completely clear of the blower wheel and that there are no other foreign ob- jects in blower wheel. Turn blower on and check for operation. Turn blower off by rotating knob fully counterclock- wise before continuing.

WARNING: Never touch the blower wheel while in operation.

7.Peel off the backing paper and stick the supplied wiring diagram decal on the inside of rear cover on right side oppo- site control.

WARNING: Failure to position the parts in accordance with sup- plied diagrams or failure to use only parts specifically approved with this heater may result in dam- age or personal injury.

8.Connect or reconnect gas supply to fire- place per Connecting Fireplace to Gas Supply on page 13 of this manual.

WARNING: A qualified ser- vice person must connect fire- place to gas supply. Follow all local codes.

mal switch.

5. Connect the black wire to the left side

of the thermal switch.

Black

White Wire

Wire

Blower

 

 

Assembly

Thermal

Green

Switch

Wire

with

Blue Wire

Bracket

Hex Head

 

 

Screws

Figure 15 - Attaching Thermal Switch to DA3610T Thermostatically Controlled Blower Accessory

Blower

Control

Control Knob

Shaft

Lock

Speed Control

 

Nut

Power Cord

Mounting Screws (Included in Hardware Pack)

White

Black

 

Wire

Wiring

Wire

 

Diagram

 

 

 

 

Decal

Blue

Green

 

Rear Cover

Wire

Blower

 

Ground Wire

 

 

Figure 16 - Installing Optional Blower Accessory (Thermostat Model DA3610T Shown)

Continued

105500

7

Page 7
Image 7
Desa SBVBN(A), SBVBP(A) installation manual Installing Optional Blower Accessory, Installing GA3700/DA3610T Blowers

SBVBN(A), SBVBP(A) specifications

Desa SBVBN(A) and SBVBP(A) are innovative solutions in the realm of wireless communication, designed to enhance connectivity and network efficiency. Each model is tailored for specific applications, making them essential tools in modern telecommunications.

One of the primary features of both the SBVBN(A) and SBVBP(A) models is their support for advanced modulation techniques. These modulations allow for higher data rates and improved spectral efficiency, which are critical for congested environments. By employing technologies such as Orthogonal Frequency-Division Multiplexing (OFDM), these systems can deliver superior performance even in challenging conditions.

In terms of connectivity, SBVBN(A) focuses on boosting signal strength over long distances. This is especially vital in rural areas where traditional infrastructure may be lacking. The system can cover expansive regions with minimal signal degradation, ensuring reliable communication. Meanwhile, SBVBP(A) is optimized for high-density urban settings, capable of handling a large number of simultaneous connections without compromising speed or quality.

The integration of artificial intelligence and machine learning technologies is another standout feature. Both models utilize smart algorithms to analyze network traffic in real-time, enabling dynamic adjustments to optimize performance. This capability is crucial in environments where user demand can fluctuate drastically, allowing for adaptive resource allocation and enhanced user experience.

Power efficiency is also a significant characteristic of Desa SBVBN(A) and SBVBP(A). Equipped with energy-saving technologies, these systems minimize power consumption while maximizing output. This not only reduces operational costs but also aligns with global sustainability goals.

Moreover, the systems are designed with scalability in mind. They can be easily integrated into existing infrastructures, providing a seamless upgrade path for telecommunication providers looking to enhance their services without major overhauls.

Security is a top priority for both products. They incorporate advanced encryption protocols and access controls, ensuring that data transmission remains secure and protecting against potential threats.

In summary, Desa SBVBN(A) and SBVBP(A) represent the future of wireless communication, with their focus on advanced modulation, AI integration, energy efficiency, scalability, and security. These features make them ideal solutions for a variety of applications, ranging from rural connectivity to urban high-density environments, thus playing a significant role in bridging the digital divide and fostering enhanced communication worldwide.