Installation

36" Island Vent Hood

Step4

Mount Template

Align the template with the marks on the ceiling and tape in place.

Be sure the template is oriented correctly, with the front of the hood.

Use a plumb to check to be sure the mount- ing holes will provide parallel alignment with the countertop below.

Center punch all hole locations.

Drill pilot holes in the 4 screw locations. Use a 5/32” bit and drill approximately 1-1/2” deep.

Cut the 6-1/4" dia. duct opening and approx. 1" dia. wire access hole.

Front of Hood

Wire Access Hole

Step5

Install

Support

Frame

Upper

Support Front

Frame Of

Hood

Lower

Support

Frame

 

Hood

 

Lower Support

 

Mounting

 

 

 

Flange

 

 

 

 

 

13-5/8

Support

 

 

 

Frame

 

 

*39-1/8"

Opening

 

25-1/2" Recommended

 

 

Check Level in

 

 

**75-1/8"

 

 

to Floor

Both Direction

 

 

Countertop

 

 

 

Install upper support frame

Secure the upper support frame to the ceiling joists and/or cross framing with the 4 screws provided. For maximum rigidity and strength, the screws must be driven into the center of the joists and/or cross framing.

Check to be sure the support frame is level, vertically and horizontally.

*Note: 39-1/8" to top of hood flange can be increased up to 42" max.

**75-1/8" min. to floor, 77-7/8" max.

Install lower support frame

Insert lower support frame (from required accessory ZX858, ZX859 or ZX8510) into the upper support frame and loosely secure with 8 screws and washers (4 on front and 4 on back sides).

Adjust the lower support frame up or down to the desired height above the countertop. Tighten screws.

Important: Again, check to be sure the support is level in both directions. There is no way to level the hood after the hood is secured to the frame.

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GE ZV850 installation instructions Install Support Frame, Install upper support frame, Install lower support frame

ZV850 specifications

The GE ZV855, ZV755, ZV850, and ZV750 represent a significant leap in the realm of modern gas turbine technology. These models, primarily used in power generation, have been engineered with an emphasis on efficiency, reliability, and environmental sustainability. Their advanced features and capabilities make them ideal for both utility companies and industrial applications.

The GE ZV855 stands out with its high efficiency and flexibility, capable of generating up to 50 MW of power. One of its main features is the innovative combustion system, which allows for a wide range of fuels, including natural gas and biofuels. The turbine design incorporates advanced aerodynamics for improved performance, while also ensuring reduced emissions of nitrogen oxides (NOx) and carbon dioxide (CO2). This makes the ZV855 an optimal choice for those looking to comply with stringent environmental regulations.

In a similar vein, the ZV755 offers versatility with a slightly lower power output, around 40 MW, while maintaining similar efficiency levels. It is designed for quick starts and operational flexibility, making it ideal for peaking power plants. The ZV755 utilizes state-of-the-art digital control systems, allowing for real-time performance monitoring and predictive maintenance, which enhances reliability and reduces downtime.

The ZV850 model is primarily tailored for combined cycle applications, achieving higher thermal efficiency. This turbine can operate efficiently in tandem with steam turbines, allowing for a significant reduction in fuel consumption. Its advanced heat recovery steam generator (HRSG) technology enables it to capture waste heat and convert it into additional power, further improving the overall efficiency of the power plant.

Lastly, the ZV750 is known for its compact design and modular construction, facilitating easier installation and maintenance. With a power output similar to ZV755, it also emphasizes low emissions and operational efficiency. The turbine includes smart grid capabilities, enabling seamless integration into modern energy management systems.

Collectively, these GE turbine models represent the forefront of gas turbine technology, highlighting a commitment to operational excellence and environmental stewardship. Their unique features and advanced technologies position them well for future energy demands, making them indispensable in the transition towards a more sustainable energy landscape.