US3513813A

US3513813A - Dilute phase particulate matter reactor-heat exchanger

Info

Publication number: US3513813A
Application number: US789046A
Authority: US
Inventors: Paul H Towson; John W Bishop
Original assignee: US Department of the Interior
Current assignee: US Department of the Interior
Priority date: 1968-12-31
Filing date: 1968-12-31
Publication date: 1970-05-26
Anticipated expiration: 1987-05-26

Description

May 26, 1970 P. H. TOWSON A!- DILUTE PHASE PARTICULATE MATTER REACTOR-HEAT EXCHANGER Filed Dec. 31. 1968 ATTORNEYS N s P mmw 5 mma W N u.

mm M mf P Y B United States Patent US. Cl. 122-4 15 Claims ABSTRACT OF THE DISCLOSURE Heat is extracted from circulating gases and particulate matter by dilute phase contact with heat exchange surfaces. In a specific embodiment, particulate coal is burned as a recirculating dilute phase gas suspension in a boiler-heat exchange chamber.

INTRODUCTION The burning of solid fuel in a dilute phase gas suspension is an established art. Usually the fuel, for example coal, is introduced into the burner area or furnace in a finely divided state. In order to insure complete combustion of solid fuel particles, significantly greater fuel retention time in the burning area must be provided as compared to oil and gas. This in turn places definite upper limits on the heat reelase per unit volume of the furnace chamber. These limits are much lower than those of oil and gas fired units thus dictating much larger furnace dimensions for the same capacity.

It is also well established that combustion within a fluidized bed can provide an extremely high heat release per unit volume and particulate fuels such as coal can be burned in such beds. By providing heat exchange means such as a coil immersed within the bed, heat exchange rates many times that of conventional systems may be achieved between the fluidizing gas, the particulate bed and the heat exchange means. Thus, the fluidized bed system offers an attractive combination of high heat release, high heat transfer and extremely small size.

However, the fluidized bed combustion system also suffers some significant disadvantages. Combustible content of the ash residue is often extremely high. Fly ash entrained in the exiting flue gas may contain as much as 70% carbon and may represent a loss of as much as 15% of the heating value of the fuel. Auxiliary systems must be employed to recover the combustibles contained in the fly ash. Another disadvantage of the fluidized bed combustion system lies in its lack of control flexibility. A fluidized bed characteristically has a small turn-down ratio; that is the ratio of maximum fluidizing gas flow to minimum fluidizing gas flow may only be varied over a small range without disruption of the fluidized bed.

It has now been found that many of the advantages of both the fluidized bed combustion and a conventional furnace may be obtained in a single unit. A combustion or reaction zone is provided having a semiclosed loop configuration in which oxidizing or reacting particulate matter is continuously recirculated. In a preferred embodiment, heat exchange surfaces are placed within the combustion or reaction zone.

DETAILED DESCRIPTION OF THE INVENTION The invention will be more clearly understood from the following description of a preferred embodiment wherein reference is made to the accompanying drawings:

FIG. 1 is a transverse sectional view of the reactor-heat exchanger illustrating a vertical baffling arrangement.

3,513,813 Patented Ma.y 26, 1970 FIG. 2 is a longitudinal sectional view of the reactorheat exchanger illustrating a horizontal bafiiing arrangement.

FIG. 3 illustrates an alternative nozzle arrangement for use in the device.

Referring now to FIG. 1, the device comprises a housing 10 enclosing a reaction volume. In this embodiment, the device is designed for the evaporation of liquids such as water. Disposed within the upper part of housing 10 is a steam drum 11 which is connected by means of heat exchange conduits 12 to a lower drum 13.

A relatively high velocity stream of oxidizing gas, preferably air, is injected into the system via conduit 14. Particulate fuel, preferably in a relatively finely-divided state, is introduced into the system by way of line 15, where, after mingling with the oxidizing gas, the fuel is injected into the reactor. Conduit 14 terminates in the central portion of a converging-diverging throat 16 and forms in conjunction with that throat an eductor-type nozzle. Kinetic energy derived from the injected air causes circulation of combustion gases and fuel particles in a semiclosed loop as shown by the arrows. Velocity of the injected air must be sufliciently great to maintain the velocity of the circulating gases above the terminal or settling velocity of the particulate material carried by the gases. Baffle member 17 extends upwardly from drum 13 so as to define a circulation path encompassing a major portion of the volume enclosed by housing 10. Member 17 may be constructed of refractory material or of a high temperature alloy and may be of water cooled construction.

A portion of the circulating combustion gases is continuously removed from the reactor through breeching 20. Concentration and size of particulate matter, generally ash, carried by the exiting combustion gases is controlled by adjusting the angle formed by the juncture of breeching 20 with housing 10. Control may also be accomplished by adjusting the velocity of the gases exiting through breeching 20 by varying the exit area.

In operation, a liquid such as water is introduced into the upper drum 11 through feed line 18. Steam generated in the heat exchange tubes 12 is liberated in the upper drum and is discharged by way of line 19. Fuel, such as pulverized coal, is injected into the reactor and circulates in a loop configuration until combustion is essentially complete. Burning coal particles and circulating fly ash impinge upon the heat exchange tubes resulting in an extremely high heat transfer rate. It is well recognized that combustible content of fly ash varies inversely with its particle size. By allowing only extremely small particles to be carried from the reactor in the existing flue gas, substantially complete combustion is assured.

Referring now to FIG. 2, there is shown another embodiment of the invention. In this embodiment housing 30 encloses a reaction or combustion volume of any convenient size and shape. As in FIG. 1, this embodiment illustrates a device designed for the evaporation of liquids such as water. A steam drum 31 is disposed within the upper portion of housing 30 and is in communication with a lower drum 32 by means of heat exchange tubes or conduits 33.

Circulation of combustion gases and fuel particles is directed in a semiclosed loop, as is shown by the arrows, by means of baffle members 34 and 35. Baflle member 34 is preferably disposed in a vertical position near one end of the device and extends from the lower drum to a point from about /3 to about /3 of the distance between the upper and lower drums. Bafile member 35 is preferably disposed in a generally horizontal attitude connecting with the upper edge of baffle 34 and providing a barrier to vertical circulation over a major portion of the area enclosed by housing 30.

Mounted on and extending through vertical baffle member 34 is a converging-diverging throat 36 forming in conjunction with conduit member 37 an ednctor-type nozzle. A relatively high velocity stream of oxidizing gas, preferably air, entering through conduit 37 causes a forced circulation of gases and fuel particles in a semiclosed loop configuration. Solid particulate fuel may be introduced into the device as a pneumatic suspension carried by the air stream entering through conduit 37. While only one eductor nozzle is illustrated, any number of additional nozzles may be used in larger devices.

As in the device of FIG. 1, a portion of the circulating combustion gases is continuously removed from the reactor via breeching 38. Concentration and size of particulate matter carried by the exiting combustion gases may be controlled by adjusting the angle formed by breeching 38 with housing 30. Effectively then, the breeching acts as a pneumatic classifier passing only the smaller sizes of particulate matter from the reactor.

In operation, a liquid to be heated is introduced into the upper drum 31 by means of line 39. Vapor generated in heat exchange tubes 33 is liberated in the upper drum and discharged from the system via line 40.

Another embodiment of the eductor nozzle and gas entry conduit is illustrated in FIG. 3. A converging-diverging throat 50 may be mounted within the reactor in the manner shown in either FIG. 1 or 2. A gas entry conduit 51 passes through reactor housing wall 52 and terminates coaxially within throat 50 to form in cooperation therewith an eductor-type nozzle. Mounted coaxially within gas entry conduit 51 is fuel conduit 53 which preferably terminates within throat 50 but beyond the end of the gas entry conduit. Particulate fuel, such as pulverized coal, may be introduced as a pneumatic suspension using air, for example, as a carrier gas.

This arrangement provides thermal shielding for the injected fuel stream until it mixes with combustion air and thereby obviates problems of premature combustion within the fuel entry conduit. The axial area between

conduits

51 and 53 functions also as a preheater for combustion air.

In any arrangement, ignition at start-up may be established by introducing preheated air or combustion gases generated by an external source through the gas entry conduit; line 14 of FIG. 1 for example. Inert particulate matter such as fly ash may also be introduced during start-up. After the device reaches fuel ignition temperature, introduction of fuel along with combustion air is initiated. If desired or appropriate, an intermediate fuel (one with a lower ignition temperature than the primary fuel) may be used to bring up the temperature within the device to the ignition temperature of the primary fuel. When this temperature level is reached, primary fuel is substituted.

Although the device has been described as being specifically useful for the purposes of heat and steam generation, it is also useful in other applications using different fuels or no fuel at all. For example, the device may be used as a heat recovery system from either hot gases or hot particulate matter. Usable heat may also be extracted from exothermic chemical reactions other than combustion. This invention may also be used for the incineration of finely divided waste materials such as sawdust, plastic scrap, sewage sludge and the like. By restricting the amount of combustion air to less than the stoichiometric amount needed for complete combustion, sewage sludge or other carbonaceous material may be used for the production of manufactured gas.

What is claimed is:

1. A heat-extracting reactor device which comprises:

(a) a reaction chamber;

(b) bafile means within the chamber positioned so that they define a flow path for the circulation of gases and suspended solids in the form of a semi-closed 4 loop encompassing a major portion of the volume en closed by the chamber;

(0) heat extraction means in contact with the circulating gases and suspended solids;

(d) means to introduce a gas stream at a relatively high velocity into the reaction chamber;

(e) means to introduce particulate material into a zone of relatively high gas velocity within the reaction chamber;

(f) means to cause circulation of gases and particulate matter contained within the reaction chamber in a semi-closed loop configuration defined by the bafile means, and

(g) means to remove a gas stream from the reaction chamber, said means adapted to control the size and amount of particulate matter carried from the chamher in the exiting gas stream.

2. The device of claim 1 wherein the heat extraction means comprise an upper vapor-liquid containing drum and a lower liquid containing drum, the drums being in fluid communication by means of a plurality of heat exchange conduits, said conduits disposed within the reaction chamber and in direct contact with circulating gases and particulate matter.

3. The device of claim 2 wherein the gas stream introduction means comprises a tubular conduit passing through an exterior wall of said reaction chamber and terminating within the chamber.

4. The device of claim 3 wherein the means to cause circulation of gases and particulate matter comprise at least one converging-diverging throat which forms in combination with said tubular conduit gas introduction means an eductor-type nozzle.

5. The device of claim 4 wherein the means to introduce particulate material comprises a tubular conduit coaxially disposed within the tubular conduit gas introduction means.

6. The device of claim 4 wherein the means to remove a gas stream from the reaction chamber comprises a duct member and wherein the angle made by the duct member with the reaction chamber may be varied so as to control the size and amount of particulate matter carried from the chamber in the exiting gas stream.

7. The device of claim 6 wherein said eductor-type nozzle is disposed within the lower drum and wherein the bafiie means extend vertically a major part of the distance between the lower and upper drums.

8. The device of claim 6 wherein the bafiie means extend substantially vertically from the lower drum at a position near one end of the reaction chamber, the vertical extension of the baffle means terminating at a point from about one-third to about two-thirds the distance between the upper and lower drums, and thereafter the baffie means extending substantially horizontally for a major portion of the distance between the vertical portion of the baflle means to the far end of the reaction chamber and wherein at least one eductor-type nozzle is disposed within the vertical portion of the baffle means.

9. A method for the contacting of particulate material and gases in a heat-extracting reaction chamber which comprises:

(a) introducing a relatively high velocity gas stream into the chamber;

(b) causing circulation of particulate material and gases within the chamber by energy exchange with the incoming relatively high velocity gas stream, said circulation being in a semiclosed loop configuration encompassing a major portion of the volume enclosed by the chamber and in physical contact with a plurality of heat exchange surfaces disposed within the chamber;

(c) maintaining the velocity of the circulating gases greater than the terminal velocity of the particles in said gases;

(d) removing a gas stream from the reaction chamber,

and

(e) controlling the size of particulate material carried from the chamber in the exiting gas stream.

10. The method of claim 9 wherein a stream of particulate material is pneumatically introduced into the reaction chamber and wherein a chemical reaction between the particulate material and the gases occurs within the chamber.

11. Themethod of claim 10 wherein the chemical re action is combustion and wherein a particulate ash-containing fuel and air are introduced into the reaction chamber.

12. The. method of claim 11 wherein a major portion of circulating particulate material comprises partially combusted fuel particles and particles of ash residue.

13. The method of claim 12 wherein the size of particulate material carried from the chamber in the exiting gas stream is controlled so that only particles comprising ash are removed from the chamber.

14. Themethod of claim 11 wherein combustion is initiated by externally preheating the incoming air stream to the selfignition temperature of the fuel.

15. The method of claim 14 wherein the incoming air stream is' preheated to the ignition temperature of an in-. termediate fuel having an ignition temperature substantially beltjw that of the primary ash containing fuel after which intermediate fuel is introduced into the chamber until the ff'chamber and circulating gases and particulate material are heated to a temperature sufiiciently high to ignite the primary fuel.

References Cited UNITED STATES PATENTS