Installation Instructions

PARTS PROVIDED - Continued

MODEL PVWG936

Hood canopy with internal blower, grease filters and lights already installed

Glass vapour catcher

Duct covers

Duct Cover support bracket

Transition (may be already installed)

Hardware Packet:

Note: the hardware packet contains several fittings material. For model PVWG936, consider what is listed below ONLY:

Allen Wrench

Lower support bracket x 2 (to attach the hood canopy)

Rubber tape (for glass vapour catcher)

Bushes x 4 (for glass vapour catcher)

6 x 20 screws x 4 (for glass vapour catcher)

Template

Use, Care and Installation Guide

10 x 60 drywall anchors x 2 (To attach duct cover support bracket)

6 x 80 screws x 6 + washers x 6 (2 To attach duct cover support bracket + 4 to attach the hood canopy)

3,5 x 9,5 screws x 14 (2 to attach the transition + 4 to attach the duct cover + 8 to attach the lower support brackets)

MODEL PVIG940

Hood canopy with internal blower, grease filter and lights already installed

Glass vapour catcher

Duct covers

Chimney structure

Transition (may be already installed)

Use, Care and Installation Guide

Hardware Packet:

Note: the hardware packet contains several fittings material. For model PVIG940, consider what is listed below ONLY:

Allen Wrench

Rubber tape (for glass vapour catcher)

Bushes x 4 (for glass vapour catcher)

6 x 20 screws x 4 (for glass vapour catcher)

Template

6 x 80 screws x 4 + washers x 4(To attach the chimney structure to the ceiling)

3,5 x 9,5 screws x 16 (8 to assemble the structure + 4 to attach the duct covers + 2 to attach the transition + 2 to attach the junction cover (may be already intsalled))

8 x 16 screws x 4 (to attach the canopy to the structure).

1 Ft = 0.3 m 1” = 2.5 cm

DUCTING OPTIONS AND EXAMPLES

Closely follow the instructions set out in this manual.

All responsibility, for any eventual inconveniences, damages or fires caused by not complying with the instructions in this manual, is declined.

Venting Methods

The hood is equipped with a transition B for discharge of fumes to the outside (Ducting version).

Models PVWS930/936 and PVWT936: Minimum Duct

Size (Ducting/Ductless version): 5" Round Pipe.

Models PVWG936 and PVIG940: Minimum Duct Size

(Ducting/Ductless version): 6" Round Pipe.

 

Models PVWS930/936, PVWT936

Model PVIG940

 

and PVWG936

 

 

 

 

 

Roof

Pitch w/Flashing and Cap

Roof Pitch

w/Flashing and Cap

 

 

 

 

 

 

PipePipe

Pipe

Sidewall Cap with Gravity Damper

Ducted Version

Ducted Version

 

 

Preparation

Do not cut a joist or stud unless absolutely necessary. If a joist or stud must be cut, then a supporting frame must be constructed.

Fittings material is provided to secure the hood to most types of walls/ceilings.

However, a qualified technician must verify suitability of the materials in accordance with the type of wall/ceiling.

Before making cutouts, make sure there is proper clearance within the ceiling or wall for exhaust vent.

Hood installation height above cooktop is the users preference. The lower the hood is above the cooktop, the more efficient the capturing of cooking odors, grease and smoke.

The hood shall be installed at 30" (76,2 cm) minimum to 36" (91,4 cm) above the countertop.

Check your ceiling height and the hood height maximum before you select your hood.

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GE PVWS930, PVWT936, PVWS936 manual Ducting Options and Examples, Model PVWG936, Model PVIG940, Venting Methods, Preparation

PVWS936, PVIG940, PVWG936, PVWS930, PVWT936 specifications

The GE PVWS936, PVWT936, PVWS930, PVWG936, and PVIG940 are part of General Electric's advanced lineup of water and wastewater management solutions. These models reflect GE's commitment to delivering innovative technology, energy efficiency, and operational reliability in the realm of water treatment.

One of the standout features of the GE PVWS936 and PVWT936 is their robust filtration capabilities, designed to handle a variety of water quality issues. These models incorporate advanced membrane technology which enhances the efficiency of contaminant removal while minimizing energy consumption. This leads to significant cost savings in chemical usage and maintenance, a valuable proposition for municipalities and industrial applications alike.

The PVWS930 model emphasizes versatility and ease of operation. It is equipped with user-friendly interfaces and remote monitoring capabilities, allowing operators to track performance metrics in real-time. This feature not only streamlines operations but also aids in proactive maintenance, reducing downtime and extending the life of the equipment.

Another notable characteristic is observed in the PVWG936, which boasts a compact design without compromising on performance. It is engineered to maximize space utilization in treatment facilities, making it ideal for sites where footprint is a concern. This model is particularly well-suited for urban settings where space limitations are increasingly becoming an operational hurdle.

The GE PVIG940 focuses on integrated growth with an emphasis on sustainability. This model goes beyond just treating water; it's designed to promote environmental stewardship by incorporating energy-efficient components and reducing carbon footprint. Its ability to integrate with renewable energy sources underscores GE's commitment to sustainable development in water management.

All these models share common technological advancements such as enhanced automation, data analytics, and IoT integration. The data analytics capabilities allow operators to make informed decisions based on real-time data, leading to improved operational efficiencies. Furthermore, the IoT integration enables predictive maintenance, ensuring that systems are functioning optimally and reducing the likelihood of unexpected failures.

Overall, the GE PVWS936, PVWT936, PVWS930, PVWG936, and PVIG940 are engineered to meet the demands of modern water treatment processes. Their advanced features, emphasis on energy efficiency, and commitment to sustainability make them exceptional choices for both municipal and industrial applications. As water scarcity and quality issues continue to challenge communities worldwide, these models present effective solutions that align with the best practices in environmental management.