Corrosion Resistance Auxiliary Air Fume Hood for Laboratory

Product Details
Customization: Available
Material: Stainless Steel
Type: Bypass Type
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  • Corrosion Resistance Auxiliary Air Fume Hood for Laboratory
  • Corrosion Resistance Auxiliary Air Fume Hood for Laboratory
  • Corrosion Resistance Auxiliary Air Fume Hood for Laboratory
  • Corrosion Resistance Auxiliary Air Fume Hood for Laboratory
  • Corrosion Resistance Auxiliary Air Fume Hood for Laboratory
  • Corrosion Resistance Auxiliary Air Fume Hood for Laboratory
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  • Overview
  • Product Description
  • Product Parameters
  • Installation Instructions
  • Detailed Photos
  • Usage Attention
  • Fume Hood Maintenance
Overview

Basic Info.

Model NO.
WJ-1800A
Function
Exhaust, Velocity Control
Feature
Corrosion Resistance, Heat Resistant, Acid & Alkali Resistant, Fireproof, Explosion Proof
Hood Type
Standard
Color
Grey
Customized
Customized
Condition
New
Product Name
Fume Hood Equipment
Worktop
20+6 mm Ceramic
Liner Material
Ceramic Fiber Board
Input Power
380V/50A
Face Velocity
0.4-0.6 M/S
Application
Environment/Institute/Biology Lab/Chemical Lab
Transport Package
Standard Export Wooden Case Packing
Specification
1800*1205*2400 MM
Trademark
Ample
Origin
Chengdu, China
HS Code
8414809090
Production Capacity
200 Set/Month

Packaging & Delivery

Package Size
1900.00cm * 900.00cm * 2100.00cm
Package Gross Weight
500.000kg

Product Description

 
Product Description


A chemical hood can be used for storage of volatile, flammable, or odiferous materials when an appropriate storage cabinet is not available. While it is appropriate to keep chemicals that are being used during a particular experiment inside the chemical hood, hoods are not designed for permanent chemical storage. Each item placed on the work surface interferes with the directional airflow, causing turbulence and eddy currents that allow contaminants to be drawn out of the hood. Even with highly volatile materials, as long as a container is properly capped evaporation will not add significantly to worker exposures. Unlike a chemical hood, flammable materials storage cabinets provide additional protection in the event of a fire.

When working with highly hazardous materials, the higher the face velocity the better.
 While it is important to have a face velocity between 0.3 m/s (60 fpm) and 0.5 m/s (100 fpm), velocities higher than this are actually harmful. When face velocity exceeds 0.6 m/s (125 fpm) eddy currents are created which allow contaminants to be drawn out of the hood, increasing worker exposures. Check with local safety regulations on the maximum face velocity before using the hood.


The airfoil on the front of a hood is of minor importance. It can safely be removed if it interferes with my experimental apparatus.
Airfoils are critical to efficient operation of a chemical hood. With the sash open an airfoil smoothes flow over the hood edges. Without an airfoil eddy currents form, causing contaminates to be drawn out of the hood. With the sash closed, the opening beneath the bottom airfoil provides for a source of exhaust air.

Product Parameters
 
                Model Specification   WJ-1500A WJ-1500B WJ-1800A WJ-1800B
External dimensions of equipment(mm) 1500(W)*1205 (D) *2400 (H) 1800(W)*1205 (D) *2400 (H)
Dimension of works pace (mm) 1260(W1)*780(D1) *1100 (H1) 1560(W1)*780(D1) *1100 (H1)
Panel material 20+6mm thick butterfly ceramics
Material of internal lining board 5mm thick ceramic fiber board
Diversion structure Lower air return
Control system Button control panel (LCD panel)
PH value control The medium is alkaline water solution; manual monitoring, and manual control through acid pump and alkali pump.
Input power Three-phase five-wire 380V/50A
Current for air fan Not over 2.8A(380V or 220V can be directly connected)
Maximum load of socket 12 KW(total of 4 sockets)
Water tap 1 set (remote control valve + water nozzle) No 1 set (remote control valve + water nozzle) No
Water discharge way Magnetic chemical pump strong discharge
Using environment For non-explosion indoor use, within 0-40 degrees Celsius.
Applicable fields Inorganic chemistry experiment; Food, medicine, electronics, environment, metallurgy, mining, etc.
Ways of Purification Spray sodium hydroxide solution, no less than 8 cubic meters/hour Spray sodium hydroxide solution.no less than 12 cubic meters/ hour
Ways of surface air speed control Manual control (through the electric air valve to adjust the exhaust air volume or adjust the height of the moving door)
Average surface air speed 0.6-0.8 m/s Exhaust air volume: 1420-1890m3/h (when door height h =500mm) 0.6-0.8 m/s Exhaust air volume: 1760-2340m3/h (when door height h =500mm)
Speed deviation of surface air Not higher than 10%
The average intensity of illumination Not less than 700 Lux; Standard white and uv-free yellow LED lamps; The illumination is adjustable.
Noise Within 55 decibels
Flow display White smoke can pass through the exhaust outlet, no overflow.
Safety inspection No spikes, edges; Charged body and the exposed metal resistance is greater than 2 mQ; Under 1500V voltage, no breakdown or flashover occurred for 1min test.
Resistance of exhaust cabinet Less than 160 pa
Power consumption Less than 1.0kw/h (excluding power consumption of fans and external instruments) Less than 1.2kw/h (excluding power consumption of fans and external instruments)
Water consumption Less than 3.2L/ h Less than 4.0L/ h
Performance of wind compensation With a unique wind compensation structure, the volume of the wind will not cause turbulence in exhaust cabinet and will not directly blow to the staff (need to connect to the air compensation system of the laboratory)
Air volume regulating valve 315mm diameter flanged type anti-corrosion electric air flow regulating valve (electric contact actuator)
 
Installation Instructions

Adequate planning and preparation is the key. The hood user should know the Standard Operating Procedure (SOP) of the hood and should design experiments so that the SOP can be maintained whenever hazardous materials might be released.
Look for process changes that improve safety and reduce losses to the environment (e.g. more accurate chemical delivery systems vs. pouring volatile chemicals from bottles).

Develop a process to evaluate research proposals ahead of time for potential emissions and look for opportunities to reduce them.
The level of protection provided by a fume hood is affected by the manner in which the fume hood is used. No fume hood, however well designed, can provide adequate containment unless good laboratory practices are used, as follow:

• Ensure  the  exhaust  is  operating  before  beginning  work.  Check  the  baffles  for obstructions. If the hood is fitted with an airflow monitor, check the monitor's status. Even while working, be alert to changes in airflow.

• When using the fume hood, keep your face outside the plane of the hood. Use the sash for partial protection during hazardous work.

• Work at least 6 inches back from the face of the hood. A stripe on the bench surface is a good reminder.

• Use appropriate personal protective equipment such as splash goggles and gloves. This enhances safety in case of catastrophic spills, run-away reactions or fire. Wear a full face shield if there is possibility of an explosion or eruption.
Detailed Photos
 
Corrosion Resistance Auxiliary Air Fume Hood for Laboratory
Corrosion Resistance Auxiliary Air Fume Hood for Laboratory
Corrosion Resistance Auxiliary Air Fume Hood for Laboratory
Corrosion Resistance Auxiliary Air Fume Hood for Laboratory
 
Usage Attention

Do not use the hood as a waste disposal mechanism. Apparatus used in a hood should be fitted with condensers, traps, or scrubbers to contain and collect waste solvents, toxic vapors or dust. Proper disposal of waste and code compliance should be practiced.

 Limit chemical storage in fume hoods. Keep the smallest amount of chemicals in the hood needed to conduct the procedure at hand.

• Do not use the hood as a storage area. Items can block airflow and interfere with containment. Store hazardous chemicals such as flammable liquids in an approved safety cabinet.

• Do not leave uncapped bottles of reagents in a hood. Although a hood is used to exhaust fumes out of the laboratory, minimizing the amount of evaporation and fuming is desirable for the environment and operator safety.

• Always use good housekeeping techniques to maintain the hood at optimal performance levels. Excessive storage of materials or equipment can cause eddy currents or reverse flow resulting in contaminants escaping from the hood.

Fume Hood Maintenance

Hoods should be evaluated by the user before each use to ensure adequate face velocities and the absence of excessive turbulence.

• In case of exhaust system failure while using a hood, shut off all services and accessories and lower the sash completely. Leave the area immediately.

 Fume  hoods should  be certified, at  least annually, to ensure they are operating safely. Typical tests include face velocity measurements, smoke tests and tracer gas containment. Tracer gas containment tests are especially crucial, as studies  have shown that face velocity is not a good predictor of fume hood leakage.

• Laboratory fume hoods are one of the most important used and abused hazard control devices. We should understand that the combined use of safety glasses, protective gloves, laboratory smocks, good safety practices, and laboratory fume hoods are very important elements in protecting us from a potentially hazardous exposure.

 Laboratory fume hoods only protect users when they are used properly and are working correctly. A fume hood is designed to protect the user and room occupants from  exposure to vapors,  aerosols, toxic  materials,  odorous,  and  other  harmful substances. A secondary purpose is to serve as a protective shield when working with potentially explosive or highly reactive materials. This is accomplished by lowering the hood sash.
 

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