New Items

Product Details:

Moisture Removal -12L/Day
Power Supply-220~240V/50 Hz
Rated Power Consumption-195 W
Water Tank Capacity-2.4 Liters 
Net Weight-9 Kgs 
Maintain Level-30%R.H-80% R.H 
Application Area-1200 Cu.ft 

Product Details:

Moisture Removal 30°C, 80% R.H :- 100L/Day     
Power supply:-220~240 V/50Hz      
Rated Power Consumption:-1400W   
Ambient Tempreture for Operation:-5-32°C    
Net Weight:- 41 Kgs 

Product Details:

A water bath is a laboratory equipment commonly used in scientific and industrial settings for a variety of purposes. It consists of a container or chamber filled with water that is heated to a specific temperature and used to incubate samples or materials at a constant and controlled temperature. Water baths are particularly useful when precise temperature control is required for various applications, such as:

1. Sample incubation: Water baths are commonly used in biology and chemistry laboratories to incubate samples at a specific temperature. This can include tasks like culturing bacteria, growing cells, or conducting enzyme reactions.

2. Melting and thawing: They are used for melting substances that are sensitive to high temperatures or for thawing frozen samples without introducing them to abrupt temperature changes.

3. Heat-sensitive experiments: In experiments where temperature fluctuations can affect results, water baths provide a stable and uniform temperature environment.

4. Chemical reactions: Water baths are used to heat and control the temperature of chemical reactions. Some reactions require precise temperature control for specific outcomes.

5. Sterilization: In microbiology, water baths can be used for sterilizing glassware, culture media, or other equipment by heating them to a specific temperature.

6. Annealing and heat treatment: In materials science and metallurgy, water baths are used for annealing processes and heat treatments of metals and other materials.

Water baths come in various sizes and designs, from small benchtop units to large-capacity models. They often feature digital temperature controls and displays, ensuring accuracy and ease of use. Some advanced models may also include features like timers, over-temperature protection, and circulation pumps to maintain uniform temperature throughout the bath.

To use a water bath, you simply fill it with the desired amount of water, set the temperature to your target value, and place your samples or materials in containers within the water bath. The water will heat up or cool down to reach and maintain the set temperature, providing a stable thermal environment for your experiments or processes.

Product Details:

Laminar airflow (LAF) is a controlled and sterile air flow system used in various industries, particularly in healthcare and research settings. It is designed to create an environment with a consistent, unidirectional flow of filtered air to minimize the risk of contamination, maintain sterility, and protect sensitive processes or products. Here are some key points about laminar airflow:

1. Principle of Laminar Flow: Laminar airflow operates on the principle of creating a continuous and parallel stream of air moving in a single direction, typically from the top of the work area to the bottom (vertical laminar flow) or horizontally across the workspace (horizontal laminar flow). This ensures that airborne contaminants are pushed away and not allowed to settle in the critical zone.

2. Applications:

   • Cleanrooms: Laminar airflow is commonly used in cleanrooms, where precision manufacturing, pharmaceutical production, semiconductor fabrication, and other sensitive processes require a sterile and particle-free environment.
   • Laboratories: It is used in laboratories for tasks such as cell culture, microbiology, and working with sensitive equipment or materials.
   • Healthcare: Laminar flow hoods are used in healthcare settings, especially in pharmacies and IV preparation areas, to maintain sterility during drug compounding.

3. Types of Laminar Flow:

   • Horizontal Laminar Flow: In this setup, air flows horizontally across the work area from the back of the unit to the front, creating a clean workspace.
   • Vertical Laminar Flow: Here, the airflow is directed from the top of the workspace downward, ensuring that contaminants settle on the floor and are removed through filters.

4. Filtration: Laminar airflow systems use HEPA (High-Efficiency Particulate Air) or ULPA (Ultra-Low Penetration Air) filters to remove airborne particles and microorganisms. These filters are highly efficient at trapping particles as small as 0.3 microns.

5. Maintenance: Regular maintenance is crucial to ensure the effectiveness of laminar airflow systems. Filters need to be replaced or cleaned, and airflow patterns should be checked to confirm they remain uniform.

6. Personal Protective Equipment (PPE): In laminar flow environments, operators often wear appropriate PPE, such as gloves, gowns, and masks, to prevent contamination from their side.

7. Validation: Laminar airflow systems are often subject to validation and certification to ensure they meet industry standards for cleanliness and airflow control.

8. Limitations: Laminar airflow is effective in controlling particulate contamination but may not be suitable for controlling chemical or biological contaminants. It is essential to consider the specific requirements of the application when selecting an airflow system.

Laminar airflow plays a critical role in maintaining aseptic conditions and ensuring product quality and safety in various industries that require a controlled environment.

Product Details:

Front full Viewing double glass door, Temp + 2°C ~ 8°C,  CFC Free R 134a Refrigerant, High Density PUF INSULATION, Power 230 V, 1 Ph, 50 Hz , 

Working Voltage Range 190 ~ 254 V

Product Details:

HMG BOGIE HEARTH FURNACE 

SALIENT FEATURES:

 1.    Rugged and durable construction.

2.    Outer casing is made up of thick mild steel with duly powder coated, gives long
        service life with extremely resistant.

3.    Multilayer insulation with vacuum formed ceramic fibre board and refractory bricks
       with low thermal mass.

4.    Parallel guided swing aside door design for providing ease of operation.

5.    Furnace design with powerful heating elements for providing fast heating rate.

6.    Fast heat up and cool down rates.

7.    Better Temperature Uniformity.

8.    Temperature Controller with PID Controllers.

9.    Power control with Thyristor units for very precise temperature Control, wear-free
        and noiseless.

10.  High mechanical durability, short heating cycle and low power consumption.

        11. Furnace is designed with powerful heating elements, i.e, FeCrAl in all sides of the
               work tube providing fast heating rate.

 

Additional Information:

• Production Capacity: 5 per month
• Delivery Time: Within 8 - 10weeks
• Packaging Details: Wooden case

A standard laboratory oven is a piece of scientific equipment used for various purposes such as drying, sterilizing, heating, and baking samples or materials in a controlled environment. These ovens are common in research, medical, and industrial laboratories where precise temperature control is required. Here are some key features and characteristics of a standard laboratory oven:

1. Temperature Control: Laboratory ovens offer precise temperature control, typically ranging from ambient temperature (room temperature) to several hundred degrees Celsius. Some models may even have the capability to reach higher temperatures for specific applications.

2. Digital Controls: Modern laboratory ovens often come equipped with digital controllers and displays for easy and accurate temperature setting and monitoring.

3. Interior Material: The interior of the oven is typically made of stainless steel or other heat-resistant materials to ensure durability and ease of cleaning.

4. Air Circulation: Many laboratory ovens have fans or air circulation systems to ensure uniform temperature distribution throughout the oven chamber. This is especially important for applications requiring consistent heating.

5. Safety Features: Standard safety features may include over-temperature protection, door locks, and alarms to prevent overheating or unauthorized access.

6. Shelves or Racks: Laboratory ovens are often equipped with adjustable shelves or racks to accommodate various sample sizes and shapes.

7. Ventilation: Some ovens have built-in ventilation systems to remove fumes or moisture generated during heating processes.

8. Size and Capacity: Laboratory ovens come in various sizes and capacities to suit different laboratory needs. They can range from benchtop models to larger floor-standing units.

9. Applications: These ovens are used for a wide range of applications, including drying glassware, sterilizing equipment, curing coatings, conducting material testing, and more.

10. Compliance: Depending on the intended use and industry standards, laboratory ovens may need to meet specific compliance and certification requirements, such as ISO, CE, or UL standards.

It's important to select a laboratory oven that meets the specific requirements of your experiments or processes. Different models may be better suited for tasks like drying glassware (gravity convection ovens) or conducting heat-sensitive experiments (precision ovens with PID controllers). Therefore, it's crucial to understand your needs and choose an oven accordingly.

Through Joule heating, a heating element changes electrical energy into heat. Resistance is encountered when an electric current passes through the element.

To cater the buyer's requirement, we provide the best quality of Furnace Heating Element in the most affordable range. Get the best price of the Furnace Heating Element.