OPEMT~G T~ SELF-CLEA~G OVEN

(continued)

How to Set Oven for Cleaning

Quick Reminder:

1.Press the AUTO SELF CLEAN pad.

2.Press the INCREASE or DECREASE pad until the desired Clean Time appears.

If the oven is too hot and you start to set a clean cycie, the word “OFF” will appear in the display. Allow additional time for cooling before you ~ to set the cycle.

1.Follow the directions in the Before a Clean Cycle section.

The self-clean cycle will automatically begin after “CLEAN” is displayed and the time for the clean cycle is set. The words “ON” and “LOCK” will appear in the display when the door automatically locks. It will not be possible to open the oven door until the temperature drops below the lock temperature and the LOCK light goes off.

4.When the LOCK light is off, open the door.

NOTE:

 

You can find out when the clean

s;~[

cycle will be finished by pressing

 

n the STOP TIME pad.

nAUTO SELF

CLEAN

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e

v

2.After closing the door, press the

AUTO SELF CLEAN pad.

3.Press the INCREASE or DECREASE pad until the desired Clean Time is displayed.

Clean Time is normally 3 hours.

You can change the Clean Time to any time between 2 and 4 hours, depending on the amount of soil in your oven.

A

The word “door” will be displayed, the word “LOCK” will flash and oven control will signal if you set the clean cycle and forget to close the oven door.

A fan may automatically turn on and off to cool internal parts. This is normal, and the fan may continue to run after the oven is turned off.

To Stop a Clean Cycle

oCLEAR 1. Press the CLEAWOFF pad.

OFF

2.When the LOCK light goes off and the oven has cooled below the locking temperature, open the door.

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GE JTP13, JTP14 warranty OPEMT~G T~ SELF-CLEA~G Oven, How to Set Oven for Cleaning, To Stop a Clean Cycle

JTP14, JTP13 specifications

The GE JTP13 and JTP14 engines represent significant advancements in the field of gas turbine technology, primarily used in commercial jet applications. Both models are known for their robust performance, reliability, and efficiency, making them popular choices among aircraft manufacturers and operators.

The GE JTP13 engine is a turbojet engine that gained prominence for its lightweight design and high thrust-to-weight ratio. It features a single spool, axial-flow configuration that maximizes efficiency and minimizes drag. One of the standout characteristics of the JTP13 is its advanced aerodynamics, which has been optimized through extensive computational fluid dynamics modeling. This results in enhanced performance across a wide range of flight conditions.

Technology-wise, the JTP13 incorporates a dual-combustor system that improves fuel combustion efficiency. This feature not only enhances thrust output but also reduces emissions, aligning with modern environmental standards. Additionally, the engine's materials are chosen for high durability, ensuring longevity and lower maintenance costs. The JTP13's simplicity in design facilitates ease of maintenance, a crucial aspect for operators aiming to minimize downtime.

Meanwhile, the GE JTP14 engine builds upon the advancements made in the JTP13, offering several upgraded features. One of its key characteristics is the increased thrust capability, catering to larger airframes and higher payload requirements. The JTP14 retains a single-spool design but introduces innovations in blade cooling technology, enabling the engine to operate efficiently at higher temperatures, thus further improving its thermal efficiency.

The JTP14 also employs advanced digital engine control systems, enhancing overall performance management and fuel efficiency. These systems allow real-time adjustments based on changing flight conditions, providing operators with a responsive engine that can adapt to various demands. The engine's noise reduction technologies further contribute to its appeal, making it a quieter option for both passengers and the surrounding environment.

In summary, the GE JTP13 and JTP14 engines exemplify cutting-edge engineering in the aviation industry. Their design characteristics, coupled with advanced technologies, pave the way for operational efficiency, reduced environmental impact, and enhanced performance, securing their place in the future of commercial jet propulsion.