Direct fired heaters find wide application, particularly in oil refineries, where they are used for the purpose of preheating petroleum or petroleum derived feed-stocks for further processing to produce such products as fuel gas, gasoline, diesel fuel, heavy fuel oil and coke. The feed-stocks are of variable composition and boiling range and require that they be preheated to varying temperatures for further processing. Some of the applications considered would be as follows:
Delayed Coking Heater Service, which is the primary focus of the subject invention, and which involves preheating of high boiling point feed-stocks, such as residua, to high temperature, and transferring the heater effluent to a coke drum where it is held for a period of time, sufficient, to convert the feed-stock charged to a product slate consisting of fuel gas, low boiling point liquids, high boiling point liquids and coke.
Direct fired heaters in this service operate at the severest conditions of any in common oil refinery service, with the exception of direct fired heaters in thermal cracking service. Thus the design strategies applicable to heaters in delayed coking service should, in principle, be applicable to other services as well, these to include:
Crude Heater Service, wherein pretreated as-received crude is pre-heated to high, but somewhat lower temperature than that used in delayed coking, prior to being introduced to an atmospheric distillation column, where a large spectrum of products are separated from one another, to yield such end products as refinery gas, gasoline, diesel fuel, heavy fuel oil, and very high boiling point residua.
Vacuum Heater Service, wherein residual feed-stocks from atmospheric distillation are preheated to high temperature, under vacuum, followed by processing in a vacuum distillation column, to separate such products from the heater effluent as gas, liquids with a wide range of boiling points and a very high boiling residuum suitable for use as a delayed coking feedstock.
Cracking Heater Service, wherein a low molecular weight hydrocarbon gases or moderate molecular weight vaporized hydrocarbon liquids, in the presence of steam, is converted to a gaseous product containing unsaturated hydrocarbon gases, such as ethylene, propylene, and other products consisting of higher molecular weight hydrocarbons. Optimum conversion is obtained by heating the steam-hydrocarbon mixtures to elevated temperature in a short residence time conventional heater, designed to provide a residence time of less than one second. Comparable operating conditions are obtainable in a heater designed in accordance with the subject invention and comprise another focus of the invention.
Conventional direct fired heaters used for the above services are usually provided with two sections, a radiant section and a convection section. The radiant section consists of a refractory lined enclosure having one or more tubular heating coils, thru which the process fluid flows. The heating coils surround a grouping of one or more burners fueled by gas, oil or other combustible. The heating coils are arranged to form a combustion chamber into which high temperature combustion products, generated by the burners, are discharged. Heat is transferred from the combustion products to the heating coils and contained process fluid, principally by radiation.
Process fluid, and/or fluid preheating for other services is usually conducted in the convection section, prior to further post-heating of the convection section streams in the radiant section or elsewhere. The convection section consists of a refractory lined enclosure containing multiple rows of closely spaced tubes, the spaces between tubes, forming multiple channels thru which flow relatively low temperature combustion products, exiting the radiant section. The combination of high velocity combustion gas flow, the low temperature of the combustion products and the relatively small radiating volume of the combustion gases result in predominately convective transfer of heat from combustion products to process fluid.
Because of the high temperature to which hydrocarbon fluids processed in the radiant section are subjected, fluids at the inside wall of the tubular radiant section heating elements experience thermal decomposition, which results in internal coke deposition, the thickness of the deposits being greatest at locations where tube metal temperatures are highest. These deposits restrict the flow of heat from the tube wall to the contained process fluid so that the tube wall temperature eventually reaches design temperature. At this point, referred to as end of run conditions, the heater must be shut down or on-stream decoking procedures initiated, to avoid tube damage. The time interval between decoking procedures is referred to as run length. Since decoking involves use of additional labor and, utilities and incurs costs due to lost production, means of eliminating or minimizing the frequency of decoking is a worthwhile pursuit.
In the case of the subject invention, used in cracking heater service, extended run lengths are obtainable without the need for heater shut down for periodic removal of tubular coke deposits, as in the case of conventional heaters. Coke instead deposits on the surfaces of the particulates used as a heat transfer medium. Such deposits are removable while the heater is in operation by adding appropriate quantities of air to the burner flue gas effluent in the vessel used for particulate preheating prior to transferring the particulates to the vessel used for feed preheating and cracking.
This invention relates to the design of a novel direct fired heater using solid particulates as a heat transfer medium, the heater consisting of two vessels, one vessel for heating a particulate stream to elevated temperature and a second vessel for heating a process feed stream to design outlet temperature with heated particulates. The first vessel consists of a refractory lined, vertical cylindrical, water jacketed containment vessel wherein metallic particulates are directed downwards by a dispersion device, the dispersion device being located at the top of the vessel, so as to directly contact a stream of upward flowing hot combustion products generated by several burners located at the bottom of the vessel, the burners being fired by gaseous, liquid or other types of fuel. After heat exchange between the hot combustion gas and particulate streams, the combustion gas stream is separated from the particulate stream, and the hot particulate stream is collected and contained in a conical cavity at the bottom of the vessel. The combustion gas stream exits at the top of the vessel, passes through a refractory lined, horizontal tube convection section, for heat recovery, and preheats a stream of incoming process fluid feed-stock in the process. A transfer line directs the preheated process fluid inlet stream to the bottom outlet of the first vessel, where it encounters and mixes with particulates, extracted from the bottom of vessel by a standpipe. Particulates and preheated process fluid feed are conveyed to a second vertical cylindrical refractory lined vessel wherein heat is exchanged between particulate and process feed streams, the feed stream being raised to design outlet temperature in the process. When the process fluid is a liquid, as in delayed coking service, a settling chamber, consisting of an enlarged section of the second vessel, allows for separation of spent particulates, process fluid vapor, and process fluid at design temperature, the liquid process fluid being transferred to downstream equipment for further processing, and vaporized process fluid being transferred to the inlet of a convection section, there joining a stream of combustion products and process fluid vapor, originating from particulates from the second vessel which enter the first vessel. Particulates coated with a thin film of process fluid, are collected at the base of the settling chamber and are transferred from the bottom of the settling chamber to a dispersion device in the first vessel, completing the flow sequence. When the process fluid is a gas or vapor, as in gas cracking, the settling chamber is used only to separate the process stream from the particulates, the processing stream being transferred to down-stream equipment for further processing.
A third vessel, termed a quench tower, utilizes a stream of liquid particulates as a heat and mass transfer medium. The quench tower is meant for use, in conjunction with the direct fired particulate heater in liquid processing heating services, for the purpose of recovering process fluid vapors from the combustion product stream exiting the convection section of the first heat transfer vessel.
The quench tower consists of a single, vertical cylindrical, refractory lined vessel, the purpose of which is to cool the combustion product gas stream, which contains a significant quantity of process fluid vapor. When cooled to a lower temperature the process vapors are condensed, recovered, recycled, and added to the incoming process fluid stream entering the convection section tube array. The tower has a top outlet, a top particulate water generating module and a bottom inlet and bottom liquid particulate receiving module. The water generating module consists of a multiplicity of small diameter tubes, uniformly spaced on triangular or quadrilateral centers, the tubes being surrounded by a reservoir of water, contained in a cavity surrounding the tubes. Water overflowing the tops of the tubes leaves the tubes as particulates, through ports located at the bottom of the tubes, and is carried downward by jets of dispersion gas. Combustion product gas leaves the vessel at a nozzle centered between an upper and lower plate to which the particulate generating tubes are connected, after first passing thru ports in the lower plate having openings of the same size and arrangement as those for the particulate generating tubes. The lower particulate receiving module is an inverted version of the top particulate generating module, and consists of a multiplicity of non-ported tubes and combustion product inlet gas ports, the tubes and ports having the same size and arrangement as those in the upper module. Incoming combustion product gas, laden with process feed fluid vapor, leaves the convection section outlet of the direct fired particulate heater, enters through an inlet nozzle centered between the upper and lower plates of the lower module, and exits as multiple upward flowing jets through inlet ports in the upper plate of the module, the combustion product gas jets flowing counter to the downward flowing particulate jets. A multiplicity of inlet module tubes conduct particulates to the lower conical receiving cavity of the containment vessel, the particulate stream coalescing to form three layers, a condensed liquid process feed stream layer, a water layer and a dispersion gas layer. The water layer is withdrawn through an outlet nozzle, and is cooled to a temperature for quench tower re-use, in a cooling tower of conventional design. The process feed layer is withdrawn through a nozzle and combined with the incoming process fluid stream entering the fired particulate heater convection section and the atomizing gas layer is withdrawn through a nozzle for reuse in the upper particulate generating module.
When the process fluid is a gas, as in gas cracking, the quench tower is dispensed with and the settling chamber need only separate the cracked process gas stream from the particulates, the cracked gas being transferred downstream for separation of the cracked product constituents from the heater effluent.
One embodiment of the invention, a direct fired particulate process heater, using particulates as a heat transfer medium, is shown in
Burners located at the bottom of the vessel are provided for atmospheric combustion product generation, combustion products heating particulates to high temperature by direct heat exchange with the particulates. A horizontal tube convection section accepts the flow of combustion products discharged from the top, side outlet of containment vessel 1, and in so doing preheats incoming process fluid contained, in the tubular elements of the convection section. A standpipe, located at the bottom of the vessel, allows particulates to exit the vessel and mix with pressurized process feed fluid. After mixing with high temperature particulates, the preheated process fluid conveys the process fluid-particulate mixture to a vessel designated containment vessel 2, and is, there, further heated to design outlet temperature.
Section L-L is an arrangement as viewed from a horizontal plane, perpendicular to the vertical center lines of containment vessels 1 and 2, and provides a plan view of the vessels and the particulate dispersion device of vessel 1. Process fluid feed, preheated in the convection section, is brought to design temperature in vessel 2, by direct heat exchange with heated particulates from vessel 1.
One embodiment of the invention, a direct fired heater, using heat resistant particulates as a heat transfer medium, is shown in
In the case of liquid feed and gaseous feed processing, an external water jacketed and internally insulated vertical cylindrical containment vessel, item 30, designated containment vessel 1, is provided, the vessel having sloping sidewalls, conforming to the configuration of the particulate-steam jets discharged from the particulate distribution and dispersion device, the particulates being heated to high temperature by direct contact and heat exchange with high temperature combustion products. A down-flow tubular convection section, item 31, accepting combustion product gas discharged from the top sidewall outlet of containment vessel 1, item 44, allows combustion product gas to flow downward across the outer surfaces of the tubular elements, item 53, and in so doing exits the convection section at a temperature above the dew-point of the process fluid vapor carried by the combustion products. In the process of flue gas cooling, incoming process fluid is preheated at the inside surfaces of the tubular elements, item 53. A settling chamber, item 32, consisting of a vertical cylindrical section of large diameter, located immediately above containment vessel 2, item 33, allows for separation of spent particulates, process fluid liquid and process fluid vapor. In the case of gaseous feed processing and the absence of a liquid phase, the settling chamber need only separate the particulates from the gaseous heater effluent of containment vessel 2, the fluid layer, item 42, being non-existent. The vertical cylindrical containment vessel, designated containment vessel 2, is a vessel wherein preheated process fluid is raised to design outlet temperature by direct contact and heat exchange with particulates at high temperature exiting containment vessel 1 through a standpipe, item 50. Flow of particulates thru vessels 1 and 2 and their component parts is as shown by items 65 and 66. An externally insulated outer tube, item 34, and item 60,
A shroud, item 62,
A second embodiment of the invention, a quench tower, provided only for use in the case of process liquid feed preheating, as in delayed coking, is used to cool combustion product gas containing process fluid vapor. In so doing, the process fluid vapor is condensed, recovered and combined with incoming feed. The quench tower which utilizes particulates of water as a heat and mass transfer medium, is shown in
A vertical, cylindrical, containment vessel, item 1, internally insulated as indicated at item 11, is provided such that streams of cool liquid water particulates, directed downwards, are heated by direct contact with surrounding streams of hot combustion products, directed upwards, the particulates cooling the combustion products and condensing the process fluid vapors contained in said combustion products. Gas for dispersion of liquid water coolant enters through dispersion gas inlet nozzle, item 2. Combustion product containment vessel discharge nozzle, item 3, directs combustion products to the inlet of a conventional thermal incinerating vessel, not shown, for the purpose of ridding the combustion products of small concentrations of process fluid vapor, so that non-polluting combustion products may be discharged to atmosphere. Water coolant inlet nozzle, item 4,
Arrangement of tubing and combustion product gas ports, in upper and lower particulate dispersion and receiving modules, are as shown by items 17 and 18, respectively of Section Y-Y. Entering combustion product exit ports in upper plate of lower quench tower particulate receiving module are as indicated by port centerlines, items 21. Tubular particulate receiving tubes in lower module of quench tower are as shown by items 22. Dispersion gas outlet nozzle, item 23, permits recycling of dispersion gas to upper module. Lower particulate receiving module is a near but inverted duplicate of the upper particulate dispersion module, both modules having tubular and ported elements, sized and arranged identically at the apices of common equilateral triangles or quadrilaterals. The arrangement used is such as to generate a multiplicity of adjacent jets, the particulate-dispersion gas jets flowing downward and the combustion product jets flowing upward. Because the arrangement and size of jets is such that the product of the volumetric jet flow and the length to port diameter ratio of all jets is approximately the same, there is essentially the same amount of gas entrainment for each jet and the net entrainment for each jet is zero. Without entrainment, the jets do not assume a typical diverging jet profile and, in the absence of divergence, there is also an absence of horizontal jet velocity components that would otherwise result in displacement of particulates from a parallel vertical path. Without such displacement, particulates assume a very desirable vertical parallel trajectory, since with a vertical parallel trajectory, an up flowing gas stream will not bypass a down flowing particulate stream, the result being a gas-liquid contact efficiency about four times better for a quench tower designed in accordance with this invention than a spray type quench tower designed in accordance with conventional practice.
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4960502 | Holland | Oct 1990 | A |
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Number | Date | Country | |
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20090107422 A1 | Apr 2009 | US |