When changing a fluid’s thermal state, there has to be a temperature difference between the two mediums for heat transfer to take place, and the heat lost by the hot medium is equal to the amount of heat gained by the cold medium, except for losses to the surroundings.
To continually transfer heat between two mediums, heat exchangers are used.
In a direct heat exchanger, both mediums are in direct contact with each other and the indirect heat exchanger, both mediums are separated by a wall through which heat is then transferred.
Outside of a heat exchanger, the predominant heat transfer is air, whilst internally ranges from water, with or without additives, to natural and synthetic refrigerants, steam and even oils, to name the most common.
All air-conditioning and refrigeration applications make use of heat exchangers and they extend to other industrial applications such as mining, power generation, military, transport, and agricultural cooling.
To start, when determining the optimal heat exchanger per application, there are several factors to consider. “Some of the most common factors include flow rates, maximum pressure inside of the heat exchanger, pressure drop, temperature parameters, system pressures, liquid viscosity and concentration, system upset conditions (start-up/shut down), space availability, expansion plans, life cycle costs and maintenance requirements. Consideration needs to be given to whether the application will endure continuous or cyclical conditions,” says Zaur Kutelya, business development manager for the Danfoss Heating Team.
All the various heat exchanger options typically have different detail requirements, as well as preferable refrigerants per application. Each heat exchanger type is therefore designed to perform under a particular application’s criteria.
Heat exchanger sizing is also a function of this application and affects every aspect of a heat exchanger coil. Other crucial considerations not already mentioned include tube sizing, material used, fin spacing and the overall construction methodology.
Further, avoidance of dissimilar metals in the HE unit removes risks such as galvanic corrosion in applications like marine vessels. Offering the multiple material alternatives allows manufacturers to provide the market with a heat exchanger suitable for a wide range of conditions, satisfying all specifications.
Physical footprint has become a significant trend in recent years as available plant room space becomes smaller. Heat exchangers present themselves in various sizes to minimise the usage of floor space on sites.
Further, market design trends are focusing on the use of natural or low GWP synthetic refrigerants, with significant attention being given to low charge systems. In the wider market, the trends have moved towards customers preferring full end-to-end solutions that minimise points of responsibility and localise all project design considerations. This approach means that each individual design decision and implementation is made with cognisance of its impact on the whole project, and therefore the best overall outcomes can be achieved while limiting expenses and errors.
A compact heat exchanger (plate HE), depending on the technology and design parameters, is a set of thin heat transfer plates compressed together to form a plate-pack which forms the heat transfer area. Each compact technology has headers and followers which hold the plate packs together. The inner working of a plate heat exchanger is to transfer thermal energy between two fluids, without the fluids mixing.
There are also different tasks for different industries and this technology was designed for a corresponding solution. In these different industries, varieties in parameters also differ between countries. For instance, in most countries, the quality of water is completely different. Flow rates and system pressure also depends on a facility’s capacity which can be different at every location and so plate heat exchangers offered a new method.
Plate heat exchangers, having a now wider application use are also generally smaller and so transportation and installation cost became lower, maintenance is easier, and they are much higher in efficiency to the traditional shell and tube system.
Danfoss is engineering technologies that enable the world of tomorrow to be better, smarter and more effective. In growing cities, we ensure the supply of fresh food and optimal comfort in homes and offices, while meeting the need for energy-efficient infrastructure, connected systems, and integration of renewable energy. Our solutions are used, for example, for cooling, air conditioning, heating, controlling electric motors and mobile equipment. Our innovative engineering can be traced back to 1933, and today Danfoss is a global leader with 28,000 employees and sales in more than 100 countries.
References & Content Credit:
Zaur Kutelya – Business Development Manager, Danfoss Heating Moscow
Jesper Fuglsang – Customer Content Specialist, Danfoss Heating
Reny George Thomas – General Manager Sondex, Danfoss UAE
Artem Khegay – Application development manager, Danfoss Heating Moscow
Ekaterina Bolshakova – Project Manager, Danfoss Heating
Push Dhillon – Head of Heating Sales, Danfoss UK
Benjamin Brits – RACA