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CAST IRON STOVE AND B-VENT BURNER SYSTEM INSTALLATION

Installing Optional Wall Mounted Thermostat - GWMT1 (Cont.)

Installing Optional Wireless Hand-Held Remote Control Accessories - GHRCB and GHRCTB Series

CAST IRON STOVE AND B-VENT BURNER SYSTEM INSTALLATION

Continued

4.Route the wire to a convenient location to mount your thermo- stat (no outside wall). IMPORTANT: The wire must not ex- ceed 25 feet in length.

The thermostat should be mounted 54" above the floor in a location where there is good air circulation. Avoid heat sources such as lamps, direct sunlight, fireplace, or heat and air con- ditioning ducts.

5.Gently remove the cover of the thermostat from the base. Grasp the sides of the cover firmly and pull to separate from the base.

6.Feed the electrical wires through the rectangular slots (from the back) on each side of the base (see Figure 35).

7.Connect one bare wire end to each terminal (“W” and “R”) of the thermostat base (see Figure 36).

8.Install the base to the wall with screws provided with thermostat.

9.Move the temperature adjustment back and forth to insure the bi-metal is free from restrictions.

WARNING: Do not connect this thermostat to a power source. Electrical shock and/or fire hazard will occur.

Feed wires through rectangular slots

Terminal “W”

W

INSTALLING OPTIONAL WIRELESS HAND- HELD REMOTE CONTROL ACCESSORIES - GHRCB AND GHRCTB SERIES

Installing Remote Receiver

1.Open bottom door on stove body.

2.Disconnect wires from THTP and TH on control valve that lead to the switch (see Figure 34, page 15). Discard switch plate, screws, and nuts.

3.Install battery into receiver battery clip and connect to terminals (see Figure 37).

4.Place receiver into valve bracket and align holes (see Figure 38).

5.Use push-in fasteners included with receiver to secure to bracket.

6.Connect the wires from the receiver to the valve at TH and THTP (see Figure 34, page 15).

Receiver

Terminal

Wires

9-Volt

 

Battery

Battery Clip

Figure 37 - Installing Battery in Receiver

Terminal

R “R”

Figure 35 - Back View of

Figure 36 - Thermostat

Thermostat Base

Base Terminal “W” and “R”

Figure 38 - Installing Remote Receiver

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106828-01C

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Desa SBVBN(C), SBVBP(C) installation manual Installing Remote Receiver, Installing Battery in Receiver

SBVBP(C), SBVBN(C) specifications

Desa SBVBP(C) and SBVBN(C) are two advanced models in the landscape of environmental and energy-efficient technologies. These innovative designs are at the forefront of sustainable construction, showcasing a plethora of features and characteristics that make them stand out.

One of the main features of Desa SBVBP(C) is its emphasis on bioclimatic architecture, which ensures that buildings harmonize with their surrounding environment. This model incorporates passive solar design principles, allowing natural light to penetrate efficiently while minimizing energy loss. High-performance thermal insulation is another significant characteristic, which helps maintain comfortable indoor temperatures regardless of external weather conditions.

Desa SBVBN(C) complements its counterpart with its remarkable integration of renewable energy technologies. Equipped with photovoltaic panels and wind turbine systems, this model harnesses natural energy sources to reduce reliance on non-renewable energy. The energy generated can be used for lighting, heating, and powering appliances, making the building self-sufficient and cost-effective over time.

Both models utilize smart technology for enhanced operational efficiency. Internet of Things (IoT) devices allow for real-time monitoring and control of energy consumption, promoting sustainable living practices among residents. Automated systems adjust lighting, heating, and cooling based on occupancy and time of day, further contributing to energy savings.

Water conservation is another crucial aspect of Desa SBVBP(C) and SBVBN(C). Both designs implement rainwater harvesting systems and greywater recycling technologies, ensuring that water usage is minimized and reused effectively. This not only lowers utility bills for occupants but also contributes to environmental sustainability by reducing the strain on local water resources.

The construction materials used in both models emphasize sustainability, utilizing recycled, locally sourced, and eco-friendly materials whenever possible. This commitment to green building practices ensures that the overall environmental footprint of the structures is minimal.

In summary, Desa SBVBP(C) and SBVBN(C) represent a paradigm shift towards eco-conscious living. Through the integration of advanced technologies, renewable energy sources, and smart systems, these models provide a blueprint for sustainable development that addresses the pressing challenges of climate change and environmental degradation. As cities around the world seek innovative solutions to improve urban living, models like these shine as beacons of hope and progress.