The Carotek Heat Exchanger Selection Guide provides a model of the heat exchanger sizing and selection process.
Heat exchangers are used throughout industrial processes whenever heat needs to be transferred from one medium to another. Understanding how to size and select a heat exchanger benefits both productivity and the bottom line.
By its most basic definition, an industrial heat exchanger transfers thermal energy from one fluid to another without mixing them. Heat exchangers can be generally classified into a few main types:
Shell and Tube heat exchangers consist of a shell enclosing a number of tubes. Because they are widely used, these versatile heat exchangers are generally well understood. The shell and tube design helps these heat exchangers withstand a wide range of pressures and temperatures.
Plate and Frame heat exchangers are compact, efficient products designed with a number of stacked heat transfer plates clamped together within a frame.
Gasketed Plate heat exchangers feature titanium or other nickel alloys for accurate fluid temperature control for heat recovery. These designs are often used for food or sanitary applications.
Brazed Plate heat exchangers are constructed without gaskets, and they are suited for greater range of pressures and temperatures. Available in materials like copper or nickel, these corrosion resistant heat exchangers are suitable for many applications.
For any given application, there is usually more than one heat exchanger design that could be used. A starting point for heat transfer solution sizing and selection is to compare models that fit the temperatures and pressures required for the process. The best type of heat exchanger depends on design parameters, fluid characteristics, space, and budget.
Generally, more than one heat exchanger model will work for a given application, so additional criteria may help in evaluating the best fit. Consider factors like future scalability, overall cost to purchase and operate, and efficiency/carbon footprint to narrow the options.
Once a heat exchanger design is selected, the most efficient size depends on operating conditions. For example, if operating temperatures vary seasonally, both the winter and summer cooling (or heating) load must be calculated. The most efficient plate exchanger model is the smallest model with the same plate corrugation that is capable of handling the flow in both seasons.
Thermodynamic equations can help arrive at the best solution, where flow, temperature, and pressure drop are all within acceptable limits. Due to the number of dependent variables in heat transfer solution sizing and selection, complex equations are often used for selecting the optimal solution. Heat exchangers can often be tailored, and specifications like the size and number of plates are often customized for the application.
Carotek is an authorized distributor of Standard Xchange heat exchangers, and Carotek engineers are specially trained to assist with finding the optimal heat exchanger to meet your specifications. The following data sheet can be used to provide the requirements for your heat transfer solution.
The image below details all of the data necessary for proper sizing. Download this guide for a fill-in version.
Heat exchanger sizing and selection requires a combination of knowledge of the heat exchanger types and options as well as knowledge of the application and environment where the unit operates.
Contact Carotek to review your needs and heat exchanger options.
Or browse our selection of heat exchangers to find the best fit for your application.
