How Fluid Chillers Work
How a Chiller Works:
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A process chiller removes heat from a heat source &#; an environment where temperature must be maintained on a continuous basis, otherwise known as the process. Heat removal is based on the principle that heat will move from a hotter source to a colder source.
A chiller comprises two main parts called circuits &#; a fluid and refrigeration circuit. These circuits, especially refrigeration, become more complex as temperature requirements drop below -40°C. With low- and ultra-low temperature cooling, system design incorporates additional cooling circuits (called two-stage, three-stage, and autocascade systems) and refrigerants.
A chiller transfers the heat from the process to the fluid circuit then to the refrigeration circuit and finally to the condenser where it is expelled.
An air-cooled condenser expels heat by blowing cool air across the condenser, moving heat into the atmosphere.
A water-cooled condenser expels heat by circulating cool water through lines in the condenser. The water moves the heat to an external cooling apparatus.
What constitutes high reliability chiller operation? It begins with design &#; matching component capacity to cooling requirements. Specifying the right components (valves, fluids, pumps, etc.) is critical. The interactive diagram below shows a chiller with single-stage refrigeration. It describes the major components of a chiller and their importance to reliable operation in the selection of a specific design.
Refrigeration Circuit
Compressor
The compressor is the heart of the refrigeration circuit; it circulates the refrigerants. Hermetically sealed (air-tight) compressors are leak proof and typically more reliable. The type of hermetic compressor used depends on the application. This includes required horsepower (Hp), noise level and footprint. Typically, reciprocating compressors are smaller, used in applications that require less than 2 Hp. Scroll compressors are used in applications requiring more than 2 Hp, low noise levels, or extended operation periods.
Condenser
The condenser removes heat from the refrigeration circuit and expels it using air or water as the transfer medium. During heat removal the refrigerant condenses, changing the refrigerant from gas to liquid. The condenser should be sized to the application; air condensers are larger than water condensers because air is a less efficient heat transfer medium than water.
Refrigerant Lines
Refrigerant lines are copper tubes that carry the refrigerant through the refrigeration circuit. The manufacturing process of these lines is critical to the chiller&#;s overall reliability. Fully brazed (metal-joining process) refrigerant lines with hermetically sealed solenoid valves prevent leaks and contamination from external sources. Proprietary refrigerant additives keep the lines free of oil and contaminants. Additionally, each refrigeration circuit is treated with a proprietary cleaning process, which prevents erosion or thinning of the tubes. Finally, every refrigeration circuit is leak tested.
Thermal Expansion Valve
The Thermal Expansion Valve (TXV) acts as a metering device that regulates the amount of refrigerant allowed into the Heat Exchanger (HTX). The TXV bulb is filled with a gas that expands and contracts based on the temperature it monitors at the outlet of the HTX. The expansion and contraction opens and closes the TXV as needed.
Heat Exchanger (Evaporator)
The Heat Exchanger (Evaporator) is where the refrigeration circuit removes heat from the fluid circuit. The Thermal Expansion Valve on the inlet of the Heat Exchanger creates a pressure drop as the refrigerant enters the Heat Exchanger. This pressure drop forces the refrigerant to evaporate (i.e. changes from liquid to gas). As the refrigerant evaporates, it expands and becomes very cold. The cold gas lines run next to the fluid lines in a counter-flow direction. This configuration ensures maximum heat transfer from the fluid as it exits the Heat Exchanger. Fully brazed heat exchangers are the most reliable and efficient design; providing the best heat transfer and leak proof protection.
Fluid Circuit
The fluid circuit removes heat from the process and transfers it to the refrigeration circuit. A variety of fluids and pump types may be used depending on the application. The fluid picks up heat from the process and is pumped into the heat exchanger where it is cooled as it circulates back to the process.
Fluid Reservoir
The Fluid Reservoir holds fluid that is not circulating through the fluid circuit. The purpose of a reservoir is twofold: to fill the lines initially and to serve as an expansion tank as the fluid expands and contracts. The reservoir may be manually filled using Fluid Fill and Vent ports or it may be connected to an external fluid supply that automatically refills the reservoir when levels are low. Typically, reservoirs are stainless steel to prevent contamination of fluid.
Pump
The pump is the heart of the fluid circuit; it circulates fluid through the fluid lines. Positive Displacement Gear Pumps and Velocity Turbine pumps are typically the most reliable and best performing pumps. Choosing between them depends on the application. Typically Gear Pumps are used when fluids are extremely viscous and exhibit a high level of lubricity. Gear Pumps need to be lubricated; they create high pressure capable of moving viscous liquids. Turbine pumps are used when high flow rates or low noise levels are required. Turbine pumps have fewer moving mechanical parts than gear pumps; they are quieter and require less lubrication.
Heat-transfer Fluids
Fluid types vary with the temperature requirements, from water at ambient and above, to water/glycol mixture below freezing, and proprietary blends below -40 to -110C.
Process Material
Heat removal can be accomplished with a variety of fluids and materials. However, their selection must be chemically compatible with the process material they will contact. For example, copper lines passing through the pump, heat exchanger and reservoir would be corrosive to cooling an aluminum-based process. Considerations for selection of wetted materials used in components making up the fluid circuit:
PROCESS LOOP MATERIAL
WETTED MATERIALS (FLUID CIRCUIT)
Copper
Cu, Brass, SS, Engineering Plastic
Aluminum 1
SS, Brass, Engineering Plastic 2,3
1. Deionized water (purified water with mineral ions removed &#; sodium, calcium, iron, copper, chloride, bromide) is a commonly used fluid to prevent corrosion of aluminum for temperatures above freezing.
2. Stainless steel, brass and plastic tubing and joints are free of oxidative ions.
3. For ultra-pure applications, stainless steel welds and finishes require a passivation process to restore its chromium oxide surface.
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Fluid Supply and Fluid Return
Cold fluid exits the chiller at the Fluid Supply port, removing heat generated by the process. Warm fluid returns to the chiller through the Fluid Return port to begin the heat extraction and cooling process again.
Controller
The controller is the traffic cop that directs chiller operations by controlling temperature, communicating chiller health and keeping records. For example, it typically monitors temperatures, process flow and reservoir level, provide notification if any variable trends to out of range, and transmits chiller information, and logs diagnostics. The controller should be compatible with your communications protocols for remote monitoring and control.
Importance of Low temperature Chiller and it's Applications
The working principle of a low temperature chiller unit begins with a compressor that circulates a refrigerant through a closed loop system. As the refrigerant flows through the compressor, it is compressed and its temperature rises. The hot, compressed refrigerant is then passed through a condenser, where it is cooled and condensed into a liquid state.
A low temperature chiller unit, like other types of chiller units, works on the principle of refrigeration to remove heat from a process or environment and maintain a specific temperature. However, the unique feature of a low temperature chiller unit is its ability to maintain extremely low temperatures with high precision.
The working principle of a low temperature chiller unit begins with a compressor that circulates a refrigerant through a closed loop system. As the refrigerant flows through the compressor, it is compresse
d and its temperature rises. The hot, compressed refrigerant is then passed through a condenser, where it is cooled and condensed into a liquid state.
Working principle of low temperature chiller
The low-temperature chiller is mainly composed of a compressor, condenser, evaporator, throttling device and control system. Its working principle is based on the refrigeration cycle. The refrigerant absorbs heat and evaporates in the evaporator, absorbing the heat of the object being cooled. Then the refrigerant is compressed into a high-temperature and high-pressure gas in the compressor, enters the condenser to release heat and condenses into a liquid. Finally, After reducing the pressure through the throttling device, it enters the evaporator to absorb heat and evaporate again, completing the entire refrigeration cycle.
In the selection of low-temperature chillers, the choice of refrigerant is crucial. Different refrigerants have different thermodynamic properties and environmental performance, so the appropriate refrigerant needs to be selected according to specific application scenarios and requirements. For example, some new environmentally friendly refrigerants, such as R134a, R404a, etc., have excellent performance in refrigeration efficiency and environmental protection performance, and are widely used in low-temperature chillers.
The importance of low temperature chiller
Improve production efficiency: In many industrial processes, such as chemical industry, pharmaceuticals, food processing, etc., temperature control has an important impact on product quality and production efficiency. Low-temperature chillers can provide a stable low-temperature environment to ensure efficient operation of industrial processes, thereby improving production efficiency.
Energy saving and consumption reduction: During the refrigeration process, the low-temperature chiller can reduce energy consumption and operating costs by optimizing the refrigeration cycle and improving the energy efficiency ratio. In addition, low-temperature chillers can also recover and utilize waste heat to further improve energy efficiency.
Guarantee product quality: Low temperature environments have an important impact on the quality and stability of many products. The low-temperature chiller can provide a stable low-temperature environment to ensure product quality stability during production, storage and transportation, thereby ensuring product quality.
Environmentally friendly: With the improvement of environmental awareness, environmental protection performance has become one of the important factors in the selection of refrigeration equipment. In the design and manufacturing process of low-temperature chillers, we pay attention to environmental protection and energy-saving performance, and use environmentally friendly refrigerants and energy-saving technologies to reduce environmental pollution and damage.
Kaydeli is a low temperature chiller manufacturer
Kaydeli is a leading manufacturer of low temperature chiller units, which play a critical role in a variety of applications across many industries. These chiller units are designed to provide reliable, precise temperature control for a range of processes, from food and beverage production to medical and pharmaceutical applications.
One of the key benefits of Kaydeli's low temperature chiller units is their ability to maintain extremely low temperatures with high precision. This makes them ideal for applications that require precise temperature control, such as freeze drying, cryogenic cooling, and other low-temperature processes.
In addition, Kaydeli's low temperature chillers are designed to be highly efficient, which can lead to significant energy savings over time.
There are many different applications for low temperature chiller units in various industries. For example, in the food and beverage industry, these chillers are often used to cool or freeze products quickly and efficiently. They are also commonly used in pharmaceutical and medical manufacturing to maintain the temperature of sensitive materials, such as vaccines or blood products, during transport and storage.
Another key application for Kaydeli's low temperature chiller units is in research and development, where precise temperature control is essential for many types of experiments. Low temperature chillers can be used to create controlled environments for testing materials or developing new technologies. They are also useful in scientific applications such as X-ray crystallography, which requires samples to be cooled to extremely low temperatures.
Overall, the importance of Kaydeli's low temperature chiller units cannot be overstated. They are critical components in many industries, providing precise temperature control for a range of processes. Whether you are working in food and beverage, medical manufacturing, research and development, or another field, a high-quality low temperature chiller unit from Kaydeli can help you achieve your goals with greater efficiency, accuracy, and reliability.
If you have any questions about Kaydeli's low temperature chiller units or would like to request a quote, please feel free to contact us.
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