GE PVWT936, PVWS930, PVWG936, PVWS936 Ceiling Installation, For Model PVIG940 only

Page 15

Installation Instructions

CEILING INSTALLATION

FOR MODEL PVIG940 ONLY

(For models PVWS930/936, PVWT936 and PVWG936 installation, please refer to paragraph "WALL INSTALLATION" on previous pages).

1.Choose the assembly height which is most convenient for the user.

2.Measure the height

“H” between the ceiling and the

floor

 

 

•establish the desired distance

“D” between the floor

and the hood

 

 

•measure the height

“X” of the hood

•you will obtain “L” by applying the following formula L = H - (D + X) .

rangemin. 24” - 30”

 

range min. 30”

 

 

gas

electrical

 

D

 

 

 

 

 

 

Once you have regulated the length of the telescopic structure, fasten the two items using the 8 screws.

Ø 3.5 x 9.5

3.Mark the centre lines of the hob or the distance on the overlying ceiling. Use the centre lines marked on the ceiling to position the assembly template.

1 Ft = 0.3 m 1” = 2.5 cm

Note the position of the front part of the hood and proceed with the installation.

Note: All fastener location must span the studs otherwise proceed as described in Step 4.

4.Remove the template and keep it. Cut the dry wall of the ceiling and remove it. Install some wooden strips of suitable length 2” x 4” between the joists to create the assembly points of the chimney flue. Use the template for the dimensions and to define the space required. Make sure you fasten the wooden strips safely and level. Consult a professional if you are having difficulty or if this is your first installation.

5.Install the outlet duct. The female end should be 4½” under the finished ceiling and fastened safely to the joists. Do not use smaller ducts than those specified.

6.Install the conduit in the position marked in the hood and measure out the length “L” from the ceiling (see installation Step 2).

7.Install the dry wall around the duct and conduit then proceed with the ceiling finish.

Template

8.Fasten the outlet duct to the female end situated 4” underneath the ceiling.

9.Position the telescopic structure adjusted previously. Fasten it to the ceiling using the 4 screws. The outlet duct and the conduit pass along inside it.

10.Insert the chimney with the grid facing the ceiling and

fasten it on the sides to the telescopic structure using 2 screws.

1 5

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Contents 350A4502P595 03-07 ATS Range HoodsImportant Safety Information Safety Precautions Filters Using the hood controlsControl Device Reset Hood OperationStainless Steel Surfaces Care and cleaning of the vent hoodTo clean the filter/s To clean the hood surfaceCare and cleaning of the vent hood Range Hood Product Dimensions Installation InstructionsFlexible ducting Duct FittingsModels PVWS930, PVWS936 and PVWT936 Optional AccessoriesTools and Materials Required Parts ProvidedVenting Methods Ducting Options and ExamplesModel PVWG936 Model PVIG940For Models PVWS930, PVWS936, PVWT936 and PVWG936 only Wall InstallationWall Installation 5 x Duct Cover For Model PVIG940 only Ceiling InstallationCeiling Installation Page Before you call for service… Ownership Registration For Canadian Customers Pour les consommateurs canadiens Range Hood Warranty Mabe Will ReplaceWhat Mabe Will Not Cover Extended Warranties Schedule ServiceParts and Accessories Consumer Support GE Appliances Website
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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.