Installation Instructions

Refrigerator

Model GTR12

If you have questions, call 1.800.561.3344 or visit our Website at: geappliances.ca.

BEFORE YOU BEGIN

Read these instructions completely and carefully.

IMPORTANT – Save these instructions for local inspector’s use.

IMPORTANT – Observe all governing codes and ordinances.

Note to Installer – Be sure to leave these instructions with the Consumer.

Note to Consumer – Keep these instructions for future reference.

Skill level – Installation of this appliance requires basic mechanical skills.

Completion time – Refrigerator Installation

15 minutes

Reversing the Door Swing

1hour

Proper installation is the responsibility of the installer.

Product failure due to improper installation is not covered under the Warranty.

REFRIGERATOR LOCATION

Do not install the refrigerator where the temperature will go below 55°F (13°C) because it will not run often enough to maintain proper temperatures.

Install it on a floor strong enough to support it fully loaded.

Do not install it closer than 5” (13 cm) next to a range.

CLEARANCES

Allow the following clearances for ease of installation, proper air circulation and plumbing and electrical connections.

Sides 1” (2.5 cm)

Top 4” (10.2 cm)

Back 2” (5 cm) from the coiling on the back to the wall

To help with proper spacing and ventilation, make sure the metal spacer or twist-on rubber bumper (at the back of some models) is in place.

LEVELING LEGS

Adjustable legs at the front corners of the refrigerator should be set so the refrigerator is firmly positioned on the floor, and the front is raised just enough that the door closes easily when opened about halfway.

To adjust the leveling legs, turn the legs clockwise to raise the refrigerator, counterclockwise to lower it.

To raise the refrigerator

7

Page 7
Image 7
GE owner manual Refrigerator, Model GTR12

GTR12 specifications

The General Electric (GE) GTR12 and GTR10 gas turbines represent a significant advancement in turbine technology, designed for power generation with an emphasis on efficiency and reliability. These turbines are engineered to meet the growing demand for clean and effective energy solutions in the industrial sector.

The GTR12 is particularly known for its high efficiency ratings and modular design, which allows for easier maintenance and upgrades. It can adapt to varying load demands, making it an ideal option for both peak and baseload power generation. One of its standout features is the advanced materials and coatings used in the turbine blades, enabling it to withstand higher temperatures and improve overall performance. Additionally, the GTR12 incorporates GE’s state-of-the-art aerodynamic design, which enhances its output while minimizing fuel consumption.

On the other hand, the GTR10 is designed for smaller scale operations, providing an effective solution for distributed power generation. This turbine also features an efficient combustion system that optimizes fuel usage while reducing emissions. The compact design of the GTR10 makes it suitable for installations where space is at a premium. It is versatile enough to be used in various configurations, including simple cycle, combined cycle, and cogeneration applications.

Both the GTR12 and GTR10 utilize advanced digital controls and monitoring systems. GE's Digital Wind Farm technology leverages data analytics and real-time monitoring to maximize efficiency and uptime. This means that operators can predict maintenance needs before issues arise, reducing downtime and maintenance costs.

In terms of characteristics, both turbines boast a robust design that ensures reliability even in challenging operating conditions. They are engineered to comply with stringent environmental regulations, thus supporting the global shift toward cleaner energy solutions.

To sum up, GE's GTR12 and GTR10 gas turbines are exemplary models of modern engineering, emphasizing efficiency, reliability, and adaptability. With advanced features such as high-performance materials, digital controls, and versatile design options, these turbines serve as integral components in the sustainable energy landscape. Their ability to integrate with renewable energy sources further solidifies their role in shaping the future of power generation. These turbines not only meet today's energy demands but also pave the way for a more sustainable and efficient energy future.