What is HLD Technology?

In growth chambers, uniform light distribution and the ability to adjust light intensity are critical factors. Traditional lighting systems are often placed vertically on doors or side walls, leading to shading issues where some samples block light for others. This results in uneven light exposure across the chamber.

HLD (Horizontal Lighting Design) technology solves this issue by placing horizontal lighting panels within the chamber, which act like adjustable shelves. These panels can be repositioned to accommodate samples of varying heights, maximizing the use of internal space.

Key Features of HLD Technology:

1. Horizontal Light Panels
   • Lighting panels are installed horizontally inside the chamber and can be repositioned for optimal space utilization.
2. Use of LED Lamps
   • Energy Efficiency: LED lamps consume less energy compared to fluorescent lamps.
   • Minimal Heat Emission: LEDs do not heat up significantly, preventing localized temperature variations near the lamps. This allows samples to be placed closer to the light panels, optimizing the internal chamber space.
   • Environmental Sustainability: Lower energy consumption reduces environmental impact.
3. Adjustable Light Intensity
   • Unlike fluorescent lamps, which require some lights to be turned off to reduce intensity (causing uneven lighting), LED lamps in HLD allow uniform light intensity adjustments across the entire surface.
4. Customizable Light Spectra
   • Plants require different light spectra at various stages of growth, such as:
     • Cool white (6500K)
     • Warm white (2700K)
     • Floura spectrum (620–660 nm) for enhanced growth and fruiting.
   • HLD technology enables users to easily adjust these spectra via a control board without needing to replace lamps, saving time and costs.
5. Consistency Over Time
   • LED lamps maintain their light spectrum over time, unlike fluorescent lamps, which degrade and lose spectral consistency.
6. Durability and Longevity
   • LED lamps last significantly longer than fluorescent lamps, reducing maintenance and replacement costs.

Advantages of HLD Technology by FG:

• Uniform light distribution across the chamber.
• Adjustable light panels for samples of varying heights.
• Energy efficiency and environmental friendliness.
• Adjustable light intensity for consistent lighting.
• Customizable light spectra (cool white, warm white, floura).
• Long-lasting and reliable LED lighting with stable spectra over time.

What is NON CUT Technology, and How Does It Work?

One of the primary challenges with refrigerated incubators is maintaining a stable temperature during cooling. Temperature fluctuations in such devices often lead to issues like repeated experiments, poor reproducibility, and financial losses for users.

To address this, FG has developed the unique NON CUT Technology, which ensures stable temperature control while offering additional benefits such as frost-free operation, effective cooling in warm environments, extended compressor lifespan, and energy savings.

How NON CUT Technology Works:

1. Traditional Cooling Systems
   Conventional cooling systems in refrigerated incubators use compressors that circulate refrigerant gas (e.g., Freon) through the cooling circuit, creating cold air in the evaporator. The compressor’s performance, type and amount of refrigerant, and circuit design significantly influence cooling efficiency.
2. Temperature Control in Thermal Incubators
   In thermal incubators, temperature stability is achieved by frequently switching the heating element (usually a resistor) on and off, controlled by precise electronic boards.
   However, applying the same on/off cycling method to compressors in cooling systems shortens their lifespan, leads to temperature fluctuations, and results in expensive compressor replacements.
3. FG’s NON CUT Solution
   Instead of frequently turning the compressor on and off, NON CUT technology regulates the flow of refrigerant entering the evaporator, which is the primary cooling agent.
   • This approach eliminates the need for frequent compressor cycling.
   • Temperature control becomes precise, achieving an accuracy of ±0.1°C, even during cooling.

Advantages of NON CUT Technology:

• Increased Compressor Lifespan
  • Reduced wear and tear by avoiding frequent start-stop cycles.
• Precise Temperature Control
  • Maintains stable cooling with high accuracy.
• Frost-Free Operation
  • Prevents frost buildup within the incubator, enhancing usability.
• Energy Efficiency
  • Optimized cooling processes reduce energy consumption.
• Effective Cooling in Warm Environments
  • Delivers consistent cooling performance, even in challenging ambient conditions.

FG’s NON CUT technology marks a significant innovation in refrigerated incubators, offering unparalleled precision, reliability, and efficiency for laboratory and industrial applications.

What is CHP Technology?

FG has introduced CHP Technology, an innovative solution to address common issues in laboratory furnace linings, such as deep cracks, breakage, and incomplete heat transfer from the heating element to the chamber. These problems often lead to higher surface temperatures on the heating element, causing it to burn out prematurely.

CHP technology utilizes a specially designed muffle that is highly resistant to heat, expansion, and contraction, effectively eliminating issues like cracking and breakage.

How CHP Technology Works:

1. Special Material Formula and Mechanical Design
   • The unique composition and structure of the muffle efficiently transfer heat from the heating element to the chamber.
   • This prevents the heating element’s surface temperature from rising excessively, reducing the risk of burnout.
2. Protection Against Harmful Vapors and Gases
   • Encasing the heating element within the refractory material shields it from the damaging effects of vapors and gases inside the chamber, significantly extending its lifespan.

Advantages of CHP Technology:

• Uniform Temperature Distribution
  • Ensures consistent temperature across all surfaces within the chamber, improving the quality and reliability of processes.
• High Shock Resistance
  • Withstands thermal expansion and contraction without cracking or breaking.
• Extended Heating Element Lifespan
  • Prevents overheating and protects against corrosive effects, reducing maintenance and replacement costs.
• Element Protection from Vapors and Gases
  • Shields the heating element, ensuring stable performance in challenging environments.

CHP technology sets a new standard for laboratory furnaces, combining durability, efficiency, and safety to enhance performance and reduce operational costs.

What is CMT Technology?

FG has introduced CMT Technology, a revolutionary design to address common issues in laboratory shakers such as noise, vibration, uneven movement, and inefficiency. Traditional shakers often use one eccentric and four springs (or rubber or similar elastic materials) to generate orbital motion, which leads to problems like uneven rotation, increased mixing time, and device instability on the workbench.

How CMT Technology Works:

1. Four-Eccentric Mechanism
   • Instead of springs at the four corners, FG uses four eccentrics.
   • This design evenly distributes the weight of the load across the entire surface of the moving platform, preventing localized pressure points.
2. Stable and Uniform Motion
   • The motion remains consistent regardless of where the load is placed on the platform, ensuring efficient and faster mixing of solutions.
3. Elimination of Noise and Vibration
   • The moving platform and device base are connected via eccentrics instead of springs, isolating the motion of the platform from the device base.
   • This prevents noise, vibration, and unwanted movement of the shaker on the workbench.
4. High Load Capacity
   • The shaker can handle loads of up to 10 kg while maintaining smooth and consistent motion.
5. No Belts or Springs
   • The absence of belts and springs simplifies the design, making the device durable and capable of continuous operation without wear and tear.

Advantages of CMT Technology:

• Load Capacity: Supports up to 10 kg on the moving platform.
• Smooth and Uniform Motion: Ensures even mixing across the entire platform surface.
• Noise and Vibration-Free: Operates silently and without vibrations, even under heavy loads.
• Permanent Operation Capability: Designed for continuous use in demanding laboratory settings.
• No Movement on Workbench: The shaker remains stable during operation, improving safety and precision.

CMT technology sets a new benchmark for laboratory shakers, combining performance, reliability, and user convenience to ensure optimal results in mixing processes.