4.The convection blower will not function normally

-Check all the connections between the controller, switch, and the convection blower against the wiring diagram.

-If the convection motor will not run, apply 115 V to the motor directly. If the motor runs, replace the fan controller. If the motor does not run, the convection blower has failed. Replace the blower.

-If the convection blower runs on high at all times (no control with the fan controller), check the connections from the 160°F (71°C) sensor (located on the upper left side of the firewall) and convection fan controller to the blower. Disconnect one of the wires from the sensor, if control of the convection blower returns to the fan controller, replace the sensor.

-If the motor is still on high, re-connect the sensor and replace the convection fan controller.

5.Igniter- the pellets will not light

-Everything else in the stove operates but the igniter will not light the pellets

-Check all the electrical connections on the 120°F (49°C) temperature sensor located on the exhaust channel.

-Check the connections at the igniter socket.

-Place a jumper wire between the two leads on the 120°F (49°C) temperature sensor. If the igniter works. Replace the sensor.

-If the igniter does not work. Replace the igniter

NOTE: The igniter should be a bright yellow or bright orange in color. If not Replace the igniter.

6.The auger motor will not function normally

-Make sure the exhaust blower is operating.

-Make sure the dial-a-fire is turned on.

-Unplug the stove and open the side and back panels.

-Check all the connections to the auger motor, auger dial-a-fire, vacuum sensor, 200°F (93°C) temperature sensor and the timing control module against the wiring diagram in this manual.

-Check the condition of the vacuum hose (located on the left side of the stove). It should not be cracked or torn and should be installed on the top air inlet tube on the vacuum sensor.

-Check the manual reset button on the 200°F (93°C) temperature sensor. If this sensor has been tripped, check for the cause of the over-heating before pushing the red button in. Check auger for movement.

-If the auger still does not work, then apply 115 V directly to the auger motor. If the auger motor does not work, replace it.

-By-pass the 200°F (93°C) temperature sensor with a jumper wire check the auger. If the auger works replace the sensor.

-Check the voltage across the load pins of the timing module. It should be around 1-2 V, cycling to line voltage during an auger pulse. If not, replace the timing control module.

-Check the vacuum sensor by placing a jumper wire between the blue wire and the black wire that are attached to the sensor. If the auger works, test to see if the exhaust blower is producing enough vacuum.

-To test the exhaust vacuum place a magnehelic gauge in the sensor end of the vacuum tube. It should read 0.5wc”. If the reading is good then replace the vacuum sensor.

-If the auger motor still does not work, then attempt to by-pass the auger dial-a-fire control by removing the leads from the timing control module’s second delay pins and

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Enviro FPI, FS, BIH technical manual

BIH, FS, FPI specifications

Enviro FPI, FS, and BIH are innovative technologies that have significantly contributed to the field of environmental protection and sustainability. These systems are designed to address various environmental challenges by utilizing advanced features and methodologies that promote efficiency and effectiveness.

The Enviro FPI (Floating Photovoltaic Installation) is a groundbreaking technology that involves the installation of solar panels on bodies of water. This approach not only generates renewable energy but also minimizes land use, which is critical in densely populated areas. The floating structure reduces water evaporation and helps maintain water quality by limiting algae growth. Additionally, the cooling effect of water can enhance the efficiency of solar panels, resulting in higher energy output.

The Enviro FS (Floating System) expands upon the principles of FPI by integrating multiple environmental functionalities. This system includes features such as water filtration and oxygenation, which are essential for improving aquatic ecosystems. The incorporation of bioremediation technologies allows for the natural degradation of pollutants, making it a multifunctional solution for water bodies facing contamination. The FS system is engineered to blend seamlessly into its environment, ensuring minimal disruption to local wildlife and habitats.

The Enviro BIH (Biodegradable Industrial Hemp) represents a leap forward in sustainable materials. Utilizing industrial hemp, this technology creates biodegradable products that can replace conventional plastics. Hemp is known for its fast growth rate and low environmental impact, making it a viable alternative for various industries. The use of BIH not only helps reduce plastic waste but also supports sustainable agriculture and provides economic opportunities for farmers.

All three technologies embody key characteristics that make them stand out in the field of environmental innovation. They are designed with sustainability at their core, emphasizing the importance of balancing human activity with ecological preservation. The integration of renewable energy generation, pollution remediation, and the use of biodegradable materials showcases a holistic approach to modern environmental challenges.

Furthermore, these technologies are scalable and adaptable, allowing for implementation in various contexts, from urban settings to rural areas. As awareness of environmental issues continues to grow, solutions like Enviro FPI, FS, and BIH play an essential role in promoting a greener and more sustainable future for generations to come. Through their combined efforts, these technologies pave the way toward a more responsible relationship with our planet.