The present invention relates to a heat exchanger for contaminated fluids which are subjected to strong variable heat load.
Such heat exchanger, of shell and tube type with in-tube gas, is provided with a new structure, optimized for such fluids. As it is known and very briefly, a shell and tube heat exchanger is a surface heat exchanger, mainly made up of a bundle of tubes arranged inside a more or less cylindrical vessel (called shell). Such a device is crossed by two currents: one current passes inside the tubes and the other one passes through the space delimited between the inner surface of the shell and the outer surfaces of the tubes. Among heat exchangers it is the most used model and allows the exchange of great heat quantities, by having exchange surfaces which can reach tens of thousands of square metres.
In one of the possible versions, there end to the shell at least two flanged gates, which are intended for the service fluid (i.e. the cooling/heating fluid used as vector of the heat exchange, generally water) and two heads intended for the process fluid (i.e. the fluid which has to be cooled/heated, which is up directly to the industrial process) to which the bundle of tubes is welded.
In the shell there can be provided transverse sheet plates, called baffle plates, which are intended to control the hydraulic regime in the same shell by increasing crossing speed and as a consequence the heat exchange coefficient.
However, the traditional shell and tube heat exchanger is not optimal in case the gas is contaminated with strong-variable load. Firstly, the tubes of the bundle of tubes, since they are crossed by a “dirty” gas, are subjected to a possible occlusion. Clearly, the occluded tube will transfer less heat than what a corresponding free and well functioning tube will do. Therefore the two tubes will be subjected to different temperatures and to consequent different thermal expansions. As a consequence, this will induce an increased stress condition in the welding zones between tubes and head, which could compromise the useful life of the element. This drawback is yet more serious if it is considered that the working fluid is subjected to sudden heat variations.
Therefore, there is the need for a new heat exchanger for contaminated gases and which are subjected to strong variable heat load, which overcomes the above described drawbacks.
Object of the invention is a heat exchanger for cooling contaminated gases and subjected to a variable heat load according to what claimed in claim 1.
The independent claims describe details and further advantageous aspects of the invention.
The different embodiments of the invention are now described by means of the examples, referring to the appended drawings, in which:
Referring to
In the same way, the annular passage G is connected at the opposite end to the outlet manifold 7 of the heated fluid, through independent tubes 5. It is to be observed that the arrangement adopted in
The contaminated gas is directed towards the bundle of tubes (inner tubes 2) through a plenum 9, and after crossing the bundle of tubes 1, flows towards an outlet flange from a plenum 10. For example, the inner tubes 2 are connected by welding at the inlet of the tube plate 12.
At the opposite end, said tubes 2 are guided by the tube plate 13 but are free to expand through the same plate tube, i.e. they are not welded to it. Referring to
According to a preferred embodiment of the invention, both the upper and lower tube plates 112, 113 are realized with a “stepped” shape or more generally they are inclined with respect to the axis of the exchanger, so that the plenum 109, 110 are provided with passage sections proportional to the fluid flow rate so that the speed of the gas inside the plenum 109, 110 and as a consequence inside the tubes 112 is almost constant.
Referring to the
The dimensioning of the wire 11 depends on the working fluid used considering the possible evaporation of the fluid during the crossing of the annular passage G and the consequent volumetric flow rate variation.
In the initial portion of the tube 1 independent tubes 5 are introduced which are welded to the bundle of tubes 1 and which make the water or cooling fluid go out from the annular passage G towards the manifold. In particular, there is a tube 5 for each outer tube 3 of the bundle of tubes.
Preferably in the final portion of the tube 1, the outer tube 3 is provided with a corrugated profile 15 able to absorb the thermal expansions of the inner tube 2. It is to be noted that the same corrugated profile is not apt for the inner tube 2 since its cleaning is not eased. Therefore, the adopted reason for the inner tube 2 is that of the end free to be deformed.
Alternatively to the corrugated profile, the outer wall can be realized in two sections, connected to a welded expansion element.
Referring to
Said seal 14 can be a suitable gasket, for example a mechanical seal, realized by a metal disk and an elastic push element, or a seal in elastomeric or metal-elastomeric mixed material (lip seal ring). The volume limiting the outer wall of the tubes is obviously in connection with the outer environment (air at atmospheric pressure). If the free end of the tube 1 is not realized as a seal, an air flow is induced by this volume to the outlet plenum 10, if, as usually, is at a pressure slightly lower than the atmospheric one.
Said vertical tubes 102 can be cleaned by any known device, preferably a helical insert which can be guided alternately or rotatingly inside the tube 102 through plugs 116 positioned in the upper portion of the plenum 109. Alternatively, an automatic brush tubular or shotblasting cleaner can be used to maintain clean the inner surface of the tube 102.
The whole bundle of tubes 1, in case of feeding break of the cooling fluid from the manifold 6, as in the case in which the flow remains but the fluid comes back to the exchanger without a suitable cooling, can be cooled by an air flow coming from the outer environment, by means of suitable blowers 18.
Preferably the system should be enclosed in a container, with dimensions and stacking characteristics according to the standards, so that the transport costs are reduced.
Concerning the fluid receiving and transporting heat by crossing the interspace G between the outer tube and the inner one, it can be any heat bringing fluid (diathermal oil, pressured water, molten salt, liquid metal as for example molten Pb, as well as the working fluid of a cycle, for example a Rankine cycle with organic working fluid.
Even if at least an embodiment was described in the brief and detailed description, it is to be intended that there exist many other variants in the protection scope of the invention. Further, it is to be intended that said embodiment or embodiments described are only example and do not limit in any way the protection scope of the invention and its application or configurations. The brief and detailed description give instead the experts in the field a convenient guide to implement at least an embodiment, while it is to be intended that many variations of the function and elements assembly here described can be made without departing from the protection scope of the invention encompassed by the appended claims and/or technical/legal equivalents thereof.
Number | Date | Country | Kind |
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BS2014A0094 | May 2014 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2015/052601 | 4/9/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/173673 | 11/19/2015 | WO | A |
Number | Name | Date | Kind |
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3144080 | Vollhardt | Aug 1964 | A |
3494414 | Warner | Feb 1970 | A |
4090554 | Dickinson | May 1978 | A |
7237602 | Arai | Jul 2007 | B2 |
9688927 | Chen | Jun 2017 | B2 |
20090008074 | Vamvakitis | Jan 2009 | A1 |
20140000845 | Vanderwees | Jan 2014 | A1 |
Number | Date | Country |
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2509897 | Sep 1976 | DE |
Entry |
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DE-2509897-A1 machine translation (Year: 1976). |
Number | Date | Country | |
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20170030653 A1 | Feb 2017 | US |