FR2577034A1 - METHOD AND DEVICE FOR THE PRODUCTION AND RECOVERY OF HEAT - Google Patents

Abstract

THE PROCESS AND THE DEVICE USING HEAT EXCHANGERS WHICH INCLUDE, AS HEAT SUPPORT, A LIQUID MATERIAL AT LOW PRESSURES UNTIL HIGH TEMPERATURES. HEATING THIS ALLOWS TO TRANSFER THE HEAT FROM A HOT GAS CURRENT 10 TO CO 2 GASIFICATION, GAS CONVERSION OR WATER DECOMPOSITION PLANTS AND TO RECOVER THE GAS HEALTH ELSEWHERE. PRODUCTS TO REDUCE THEM IN PROCESSES 6, 22.

Description

i The invention relates to a method and a device for

  production and recovery of heat by means of heat exchangers.

  In a series of industrial applications such as

  coal zeification using air or oxygen and

  water vapor, gas conversion, for example, decom-

  position of methane into a mixture of carbon monoxide and

  hydrogen, as well as the decomposition of water by pro-

  thermochemical or by electrolysis at el.e-

  vee it. It is necessary to preheat the starting materials introduced such as air, oxygen or other gases such as

  that] has water vapor at high temperatures.

  So, for example, in the case of gasification of

  coal by oxidation there. it is an endo-

  thermal comprising infrastoichiometric combustion This gasification by oxidation can be carried out by means of air or oxygen thanks to the addition of steam

  of water. The high temperatures required for gasification

  cation can be obtained only by partial combustion of coal or by partial combustion of coal and preheating of air or oxygen

  necessary for gasification, and] .a injected water vapor

  tee. A high preheating temperature for air or oxygen and for water vapor promotes the kinetics of

the reaction.

  Such a high preheating temperature of air, oxygen, other gases and water vapor can be

  obtained, if one burns part of the gas obtained by the

  coal zeification to heat air, oxygen or gas preheaters, as well as a steam superheater. This part of the gas produced is obviously lost for other processes so that the gasification installation must be dimensioned not only for a certain quantity of gas produced, but also for the production of the combustible gas necessary for preheating. In addition, provision should also be made between

  ] 'gasification installation and preheating installation-

  pipes for air or preheated oxygen as well as for superheated steam. In these conduits, pressure losses, heat losses and thermal expansions appear, which depend on the flow rates and

  pressures and which require high spending on material

  rials. To this must be added the dimensions of the conduits.

  The remarks are similar for gas conversion,

  for example, the decomposition of methane into carbon monoxide

  bone and hydrogen, whereas in the case of decomposition

  sition-of-water, the necessary reaction energy must be supplied from outside. It is common to the three cases that

  ] 'heat supply at a high temperature level fa-

  cilitate the process or even make it possible.

  The object of the present invention is to provide a pro-

  and a device for the production and recovery of heat, thanks to which it is possible to transport heat at a high temperature level with low pressure losses and low heat losses, as well as without particular installation costs, the

  production yield and heat recovery

  their, as well as that of the corresponding process. to be in front

as high as possible.

  The object of the present invention is achieved, in the case of a process of the aforementioned type, by the use of a liquid heat carrier at low pressures up to high temperatures, preferably sodium,

  which has a high heat capacity and a

  remarkable thermal ductility. Sodium can circulate

  cooked closed to heat heat at a high temperature from a source and to transport, under low pressures, enormous quantities of heat in ducts of small section and transfer it to the starting materials, in

  heat exchangers. Since sodium is] i-

  that at 1000 C and boils, at atmospheric pressure, only at around 8900 C, it can transport heat in this temperature range, in a circuit which is not under pressure, apart from a pressure intended to balance friction losses, without a phase change taking place. Furthermore, the saturation temperature of sodium increases sharply with increasing pressure, so that it can also transport, in the liquid state, from heat to higher temperatures, under relatively low pressures (e.g.

  example 1000 C at about 2.7 bars). Weak sec-

  ducts and low pressures allow

  to solve, thanks to]. 'uti] .isation of sodium,

  cu] tes of thermal expansion, thermal insulation and resistance of materials, in the case of distances of

  heat transport at high temperature level,

  me they appear in the above processes,

to] 'eche]]. e industriell]] e.

  Preferably, the heating of the preheating devices

  air, oxygen or other gases and an excess

  steam heater can be performed by a source of

  heat tell]] e that] .e smoke gas stream from a device

  combustion or the helium gas stream of a reac-

  high temperature. The choice of the flue gas stream of a combustion plant as a heat source has the advantage that it is possible to use any fuel of even lower quality - for the production of said stream of flue gas. smoke which is withdrawn] .a heat to] 'inject, by means of the sodium circuit, in the installations of

  coal gasification, gas conversion and de-

  water composition. If heat is removed from the helium gas stream from a high temperature reactor,

  injects nuclear heat into processes.

  If gasification is carried out with air, the gas produced achieves a higher calorific value, thanks to

  at the high air preheating temperature and

  corresponding heating of water vapor, since] a quantity of heat intended for preheating the air and

  overheating of the steam is not linked to the com-

  infrastoichiometric bust of the gasification plant

  cation and, therefore,] has the corresponding nitrogen fraction

  laying this part of the combustion air is not introduced into the gasification process. Direct transfer of heat from flue gases or helium to

  gas and steam, in production facilities

  gas reduction and gas conversion, cannot be performed

  killed, since large volume flows should be conducted in huge pipeline installations

  resistant to heat and pressure, which are difficult to

  thermal expansion, insulation and resistance tees could not be solved and whose size would be

too high.

  Since during the gasification of coal,

  ] a conversion of gases and decomposition of] water, tem-

  high peratures appear in the gases produced, we can take advantage of the sensible heat contained in them, in addition, by heat exchangers gas product - sodium,

  mounted as a result of the gasification installations of the tank

  good, gas conversion and water decomposition, as well

  only by means of air preheating and

  steam generation or superheating of steam and other gas preheating devices, supplied with

] e heated sodium.

  We can also imagine exchanging heat in

  the case of interconnected cycles, for example, gasification

  cation of carbon by means of oxygen and water vapor and the decomposition of water between these cycles via the circuit

sodium.

  In a device for implementing the method, one

  also has a smoke gas heat exchanger -

  sodium in the combustion chamber of a steam generator or in the helium gas stream of a reactor

  at high temperature and a pre-

  air heating and / or steam superheating and / or another gas heating device with heated sodium. In the combustion chamber of a steam generator,

  there is a sufficient amount of heat

  health, at a high temperature level, for preheating

  air or oxygen rage and steam overheating, since temperatures are widely reached here

  greater than 10,000 C. The smoke gas heat exchanger -

  sodium can be arranged in the combustion chamber of the

  steam trap, in a convenient place to sample

  heat sink, while the heavily stressed parts

  tees of the combustion chamber of the steam generator are cooled, as before, by water and therefore have temperatures noticeably more low on the walls.

  Another advantage is that it was not born

  stop requiring fuels of particular quality for combustion in the steam generator, tell.e

  so that we can also transfer, via the circuit of so-

  dium, from heat to gasification of coal, which comes from a fuel which may not be suitable

  or only very little for coal gasification.

  To this must be added the high thermal capacity of sodium

  and its low flow resistance, in liquid state

  properties which make sodium particularly ade-

  quat for heat transfer at one temperature level

  high, over long distances, such as those found

  ve between a steam generator and a

  gassing or gasification of coal. Transfer of such amounts of heat by means of high gas streams is impossible due to difficulties resulting from thermal expansion and insulation, pressure drops

  in gas flows and expenditure on equipment intended

born in canals or conduits.

  The high thermal conductivity of sodium, on the other hand as well as its heat transfer circuit operating without pressure or under low pressure allow the construction of heat exchangers which cause only low pressure drops in the air streams,

steam or gas to be heated.

  Since, during the gasification of coal,

  high temperatures appear in the installation

  version of gas and / or decomposition of water, we can take advantage of the sensible heat contained in the gas

  product, according to the invention, by means of a heat exchanger

  their gas produced - sodium mounted to] following installation

  gasification and / or gas conversion and / or decom-

  position of the water as well as by means of a generator of

  fear and / or an air preheater, a] imen-

tee (s) with heated sodium.

  The invention is described in more detail below, in support of an embodiment represented in the form of a

block diagram in figure.

  In the case of the example, it is a coal gasification installation combined with a steam power plant. In a grinding installation 1, coal dust is produced which is introduced into a gasification reactor 2. The product gas is drawn off from the gasification reactor 2, via a gas pipe 3. The air necessary for the gasification is pulsed by means of a compressor 4

  in an air duct 5 and reaches the gasifier reactor

  cation 2. The conduit 5 includes a preheating device

  air 6 which receives heat from a heat circuit

  dium 7 which is equipped with a sodium pump 8. The steam necessary for gasification is produced in a steam generator 22 which is supplied with fresh water by

  a pump 23 and a conduit 24. If one supplies the general

  steam generator 22 with steam it acts as a sur-

  steam driver. The sodium recovers the heat from the flue gases of combustion 10 of a steam generator 11, in

  the sodium heater 9.

  The steam produced in the evaporator 13 of the steam generator first passes through a superheater 14 and then arrives in a steam turbine 16 comprising a high pressure stage and a low pressure stage. The steam turbine 16 drives a generator 12. An intermediate superheater 15 is arranged between the high pressure stage and the low pressure stage of the steam turbine 13. The steam turbine 16 has connections 15 which serve to preheat the water feed into a feed water preheater 19. The steam leaving the steam turbine 13 condenses in a condenser 17, is pulsed, by means

  of a condensate pump 18, in the preheating device

  feed water 19 and is conducted in the general-

  steam generator 11 by means of a feed water pump 20. But the sodium circuit 7 also takes the heat contained in the gas produced, using a heat exchanger 21, to transfer it, with the heat from the

  sodium heating device 9, to the preheating device

  the air 6, as well as the steam generator 22. In the block diagram, the sodium heating device 9 housed in the steam generator 11 and the heat exchanger 21 supplied with sodium are mounted in parallel in the gas stream just like the device for preheating

  air 6 and steam generator 22.

  Depending on the amount of heat and the temperature,

  may provide for series connections of these heat exchangers

  their. Instead of the heat source that is fed into the

  combustion 12 by burning coal, we can also

  ment provide a high temperature reactor in which the heat released by nuclear reactions is transferred, via

  a helium circuit, to the sodium heating device 9.

  In the case of gasification by means of oxygen instead

  of air, oxygen is supplied to the gasification plant

  cation of coal 2, via compressor 4 and line 5,

  said oxygen being heated in the preheating device

fage 6.

  Instead of installing coal gasification 2, one can also provide an installation for gas conversion or water decomposition. In this case, the feed of coal from the grinding plant 1 is omitted. It is then preheated, in the case of the installation.

  for separation of gases, methane and, in the case of installation

  decomposition of water, steam or other chemicals through the sodium circuit,

  up to high temperatures.

  Thanks to the method and the device of the invention, it is

  possible to transport heat at a temperature level

  high ture, from coal burnt in normal combustion or from nuclear fission in high temperature reactors, economically and technically

  possible, over distances due to the dimensions of the installation

  lation, in installations in which endothermic processes are carried out at high temperature. Among

  these include the gasification of coal, the

  version of gases and]. decomposition of] water. Thanks to the

  baked sodium according to the invention, these procedures can be

  implemented on an industrial scale.

Claims (9)

  1. Process for the production and recovery of heat   by means of heat exchangers characterized by an exchanger   heat gor comprising a liquid heat carrier at low pressures up to high temperatures.   2. Method according to claim 1 characterized by the use   sation of sodium as a heat carrier.   3. Method according to claim 1 or 2, characterized in that the heat is withdrawn from the flue gas stream of a combustion plant.   4. Method according to claim 1 or 2 characterized in that the heat is withdrawn from the current of helium gas   from a high temperature reactor.   5. Method according to claim 1 or 2 characterized in that   heat is recovered in the gas stream   produced in a coal gasification installation.   6. Method according to claim 1 or 2 characterized in that   that the heat is recovered in the gas stream pro-   produced in a gas conversion installation.   7. Method according to claim 1 or 2 characterized in that   that heat is recovered in the pro-gas stream   duit in a water decomposition installation 8. Device for implementing a method according to   claims 3 and 4, characterized by a heat exchanger   heat flue gas - sodium (9) housed in the combustion chamber of a steam generator or in the current   helium gas from a high temperature reactor   and by an air preheating device (6)   powered by heated sodium and / or a safety device   heating of steam (22) and / or other devices gas heating.   9. Device for implementing a method according to   Claims 5, 6 and 7, characterized by an exchanger   heat gas product - sodium (1) installed following a coal gasification installation (2) and / or a gas conversion installation and / or a   installation of water decomposition and a generator   steam generator (22) and / or an air preheater (6) and / or other heating devices   gas, supplied with heated sodium.