Less expensive as compared to Plate type coolers.The various types of baffles are existing and their type, spacing, shape, will depend on the flow rate, shell side pressure drop, required tube support, flow vibrations, etc.Īdvantages of shell and tube type heat exchanger : This increases the turbulence of shell-side fluid and improves heat transfer. The baffles provide the support to tubes and also deflect the fluid flow approximately normal to tubes. baffles shell and tube heat exchanger diagram The main components of this type of heat exchanger are: One fluid inside the tubes while the other over the tubes. The tube axis parallels to that of the shell. Shell and tube heat exchanger consists of a bundle of round tubes placed inside the cylindrical shell. Food industries Shell and tube type heat exchanger Plate fin type heat exchanger is as shown in figure plate type heat exchanger diagramĪpplications of plate type heat exchanger:ĭ. They are more suitable for gas to gas applications. The fins may be plain fin (Straight or corrugated) or interrupted and are attached to the plate by brazing or soldering. The counter flow or parallel flow arrangement can also be possible. A typical cross-flow, both fluids unmixed arranged is shown below, in which heat is transferred between fluid “A” and fluid “B”. Fins from the individual flow passages for single fluid. This improves the effectiveness of the heat exchanger. It also has fins attached over the primary heat transfer surface so as to increase the heat transfer area. The plates separate the two fluids which flow through passages alternately formed between the plates.
#Tema exchanger types series
It consists of a series of closely spaced parallel plates with fins held in between. Pipe in pipe heat exchangers diagram Plate type heat exchangerĬonstruction and working of Plate type heat exchanger. Then pipe sizes, pipe lengths, and a number of bends can be determined. That together with an estimated overall heat transfer coefficient allows calculation of the required heat transfer surface area. The flow pattern and the required heat exchange duty allow calculation of the log mean temperature difference.
Crossflow just doesn’t work for a double pipe heat exchanger. A double pipe heat exchanger will typically be either counterflow or parallel flow. In a double pipe heat exchanger design, an important factor is the type of flow pattern in the heat exchanger. These would always be longitudinal fins, rather than the more common radial fins used in a cross-flow finned tube heat exchanger. Some heat exchanger advertises the availability of finned tubes in a hairpin or double pipe heat exchanger. A hairpin heat exchanger may have only one inside the pipe, or it may have multiple inside tubes, but it will always have the doubling back feature. The term ‘hairpin heat exchanger’ is also used for a heat exchanger of the configuration in the diagram. The pipes are usually doubled back multiple times as shown in the diagram at the left, in order to make the overall unit more compact. The wall of the inner pipe is the heat transfer surface. One fluid flows through the inside pipe and the other flows through the annulus between the two pipes. Working: A double pipe heat exchanger, in its simplest form, is just one pipe inside another larger pipe. However, due to the need for removable bundle construction and the ability to handle differential thermal expansion while avoiding the use of expansion joints (often the weak point of the exchanger), the current U-shaped configuration has become the standard in the industry. In its classical sense, the term double pipe refers to a heat exchanger consisting of a pipe within a pipe, usually of a straight-leg construction with no bends. Hairpin heat exchangers (often also referred to as “double pipes”) are characterized by a construction form which imparts a U shaped appearance to the heat exchanger. Classification according to the phase of the fluid. Classification according to a number of fluids:ħ.