Classifications

• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
  • B01J—CHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
  • B01J19/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
  • B01J19/14—Production of inert gas mixtures; Use of inert gases in general
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
  • B01J—CHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
  • B01J7/00—Apparatus for generating gases
• • C—CHEMISTRY; METALLURGY
  • C21—METALLURGY OF IRON
  • C21D—MODIFYING THE PHYSICAL STRUCTURE OF FERROUS METALS; GENERAL DEVICES FOR HEAT TREATMENT OF FERROUS OR NON-FERROUS METALS OR ALLOYS; MAKING METAL MALLEABLE, e.g. BY DECARBURISATION OR TEMPERING
  • C21D1/00—General methods or devices for heat treatment, e.g. annealing, hardening, quenching or tempering
  • C21D1/74—Methods of treatment in inert gas, controlled atmosphere, vacuum or pulverulent material
  • C21D1/76—Adjusting the composition of the atmosphere
  • C21D1/763—Adjusting the composition of the atmosphere using a catalyst

Definitions

• the present invention relates to an endothe ⁇ nic gas generator suitable for use with heat treatment furnaces of the kind in which metal objects are heat-treated under the influence of a process gas produced in the generator through catalytic reaction of a gas mixture.
• the gas generator includes an outer, hollow cylindrical casing, an inner tube which extends within the casing in coaxial spaced relationship therewith and which incor ⁇ porates at least one burner pipe and at least one air supply pipe, a catalytic bed located inwardly of the outer casing, and outlet openings for the exit of gases generated in the catalytic bed.
• Such gas generators are often used in heat treatment furnaces of the kind which are already equipped with simple radient tubes intended for heating purposes, wherein one or more such gas generators are placed in the location of said burners.
• the preamble of Claim 1 defines the construction of one such known gas generator which is intended to produce by catalytic reaction between natural gas and air a shielding gas for the heat treatment of metallic objects, e.g. for annealing and carbonitriding such objects.
• the known generator arrangement is also provided with furnace insulation which is effective in insulating the interior of the furnace. The purpose of this insulation is to prevent variations in furnace temperature from having a negative influence on the production of said shielding gas.
• one object of the present invention is to modify and to improve the gas generator defined in the preamble of Claim 1, so as to enable the temperature gradients in the catalytic bed to be controlled rigo ⁇ rously and therewith obtain an improved composite pro ⁇ cess gas for supply to the treatment furnace.
• the single figure of the drawing illustrates schemati ⁇ cally an inventive gas generator 1 which comprises a cylindrical, hollow casing or jacket 2, a first circular end wall 3 and a second circular end wall 4.
• a number e.g. four, of radially extending spacer members 31 which connect the outer casing 2 of the generator 1 with a disc-shaped element 32.
• a circular body 33 Provided on the side of the element 32 remote from the spacer members 31 is a circular body 33, the free end 34 of which tapers to a point.
• the gas generator 1 is passed, with said pointed end first, through an opening in a first furnace wall 51 and is moved axially until the second end wall 4 comes into contact with the outer surface of said first fur ⁇ nace wall 51.
• the circular body located externally of the disc-shaped element will then project into an open ⁇ ing in a furnace wall 52 located opposite said first wall 51.
• the distance between the second end wall 4 of the generator 1 and the disc-shaped element 32 is equal essentially to the sum of the thickness of wall 51 and the internal width.of the furnace.
• the cylindrical outer casing or jacket 2 of the gener- ator 1 comprises an outer tube 21 and an inner tube 23 which extends concentrically with the outer tube 21.
• the outer tube 21 is located between the end walls 3 and 4, whereas the right-hand side of the inner tube 23 (as seen in the drawing) is connected with the end wall 3 and extends through a central opening 35 in the second end wall 4 (shown to the left in the drawing) and is connected with a flange 5 or to a flange-shaped end wall spaced from the end wall 4.
• the inner tube 23 of the casing 2 is provided with an outlet 6 at a location close to the second end wall 4 and between said wall and the flange 5.
• the tube 23 is also corrugated in a region thereof located between the outlet 6 and the flange 5.
• Heat insulating material e.g. mineral wool, is placed in the space 22 defined by the two tubes 21, 23 and the end walls 3, 4.
• the chamber 10 is defined by two mutually spaced and mutually concentrical tubular walls 7, 8, said walls also being concentrical with the outer casing 2.
• the outer wall surface of the tubular wall 7 of the chamber 10 is spaced from the inner tube 23 of the casing 2.
• An annular end wall 11 connects the tubular walls 7, 8 at the ends thereof located nearest the end wall 3.
• the end wall 3 is located at a rela ⁇ tively short distance from the annular end wall 11.
• the outer end of the outer cylindrical wall 7 of the chamber 10, i.e. the end opposite the annular end wall 11 is connected to and terminates in the flange-like wall 5.
• the inner cylindrical wall 8 is longer than the outer tubular wall 7 of the chamber 10 and extends through an opening 9 in the flange-like wall 5.
• the chamber 10 further includes a third tubular member 12, the outer end of which passes through the opening 9 in the flange- like wall 5.
• the outer diameter of the tubular member 12 is equal to the diameter of the opening 9 and said member thus abuts the inner peripheral surface of said opening.
• the tubular member 12 extends into the chamber 10 and also beyond the end wall 4. The distance from the inner end of the member 12 to the plane of the end wall 4 corresponds to the thickness of the furnace wall 51.
• the tubular member 12 extends concentrically with the walls 7, 8 of the chamber 10.
• the internal diameter of the tubular member 12 is slightly larger than the outer diameter of the tubular wall 8.
• the space 20, which forms part of the chamber 10 and which is de ined by the outer surface of the tubular member 12 and a corre ⁇ sponding length of the inner surface of the tubular wall 7 between the flange 5 and the inner end of the tubular member 12, is filled with an insulating material.
• the tubular wall 8 has provided thereon an annular wall 13 which is spaced from the annular end wall 11 in a direction towards the second end wall 4.
• the inner peripheral surface of the annular wall 13 is spaced from the outer surface of the tube 7, such as to form an annular gap 14.
• the annular wall 13 may also connect the walls 7 and 8, wherewith openings provided in the wall 13 connect the two spaces or chambers 15, 17 separated by the wall 13.
• the chamber space 15 defined by the walls 7 and 8, the annular wall 13 and the end of the tubular member 12 is filled with a catalyst, normally a particulate catalyst. These catalyst particles have a size which prevents said particles from passing through the annular gap or openings in the wall 13, and also through the annular channel 16 formed by the mutually concentric tube 8 and tubular member 12.
• a tubular perforated wall or net structure may optionally be arranged between the walls 7 and 8, at the inner end of the tubular member 12.
• the space 17 defined by the walls 7, 8, the end wall 11 and the annular wall 13 communicates with the ambient surroundings of the gas generator 1 through a plurality of tubular conduits 18, which are disposed in a ring and which extend through the annular wall 11, the gap de ⁇ fined between the wall 11 and the wall 3, and also through the end wall 3.
• the tubular conduits 18 have outlet orifices 43 located in the end wall 3, these orifices 43 being directed towards the disc-shaped element 32.
• a further flange-like wall 19 Spaced from the flange-like wall 5, to the left of the figure, is a further flange-like wall 19 which has a central opening that surrounds the tube 8.
• a corrugated tube 53 Located between the flange-like walls 5 and 19 is a corrugated tube 53 whose diameter is substantially equal to the diameter of the wall 23.
• the tube 53 forms, together with the flange-like walls 5 and 19 and the tube 8, an annular chamber 24 which communicates with the annular channel 16, through openings 25 provided in the tube 8, and therewith also with the catalytic bed in the space 15.
• the chamber 24 also communicates with a source (not shown) of air and fuel, through a conduit 50 which extends through the flange-like wall 19.
• the fuel is normally natural gas, i.e. a mixture of predominantly methane together with other low molecular alkanes, although a mixture of alkanes of another composition than natural gas, or solely an alkane, e.
• the outer part of the tubular wall 8 also forms the outer casing wall of a burner 26.
• the tubular wall 8 extends beyond the end wall 19 and passes through a central opening in said wall, said tubular wall 8 being sealingly embraced by said opening.
• the burner 26 in ⁇ cludes three mutually concentrical tubes 8, 27 and 28, of which the tube 8 is the outermost tube and the tube 28 the innermost tube.
• the left-hand end of the tube 8, as seen in the drawing, has arranged thereon an annular end wall 29 which sealingly embraces the innermost tube 27 of the burner 26.
• An inlet opening 30 for oxygen- containing gas is provided in the tubular wall 8 at a location between the end walls 19 and 29.
• a fuel inlet 37 is provi ⁇ ded in the innermost tube 27, between the tubular walls 29 and 36.
• the left-hand end of the tube 28 is connected to a circular end wall 38.
• the tubes 27 and 28 extend into the cylindrical space defined by the tube 8.
• the inner, i.e. in the figure the left-hand end of these tubes 27, 28 is located approxi ⁇ mately level with the inner end of the tubular member 12.
• the inner end of the tubes 27, 28 will be located closer to the end wall 4 than the inner end of the tubular member 12.
• the tubular walls 27, 28 are held in their respective positions in the tubular wall 8 by spacer elements not shown.
• An annular collar 39 is spaced at a short distance from the inner end of the tube 27.
• An annular gap 40 is defined between the outer peripheral surface of the annular collar 39 and the tube 8.
• the gas generator 1 is also provided with a narrow-bore conduit through which small samples of the gas produced can be taken.
• the inner end of the conduit is located within the space 17, which communicates with the cataly- tic bed in the space 15, and extends from the space 17 along the tubular wall 7, to the external surroundings of the generator 1, through openings (not shown) pro ⁇ vided in the walls 5 and 19.
• the catalytic bed has provided therein at least one temperature res- ponsive body.
• the temperature responsive body is con ⁇ nected to electrical conductors located adjacent the inner surface of the tubular wall 7 and extending to the external surroundings of the generator, where said conductors are connected to control equipment.
• the inner end of the burner 26 is formed by the inner ends of respective tubes 27 and 28.
• the space 41 is an extension of the burner gas channel 42.
• the outer casing 2 presents in the tube 23 the outlet 6 for burner gases.
• the gas generator 1 is placed in a treatment furnace and supplied with air or some other oxygen- containing gas, through the inlet 30 of the burner 26.
• the oxygen containing gas then flows into the annular space between the tubular wall 8 and the wall 27, and through the gap 40 defined between the peripheral sur ⁇ face of the collar 39, and the tubular wall 8.
• Tur ⁇ bulence is imparted to the flow of oxygen-containing gas on the downstream side of the collar 39, so that the gas will readily mix with natural gas flowing between the tubes 27 and 28.
• the fuel is supplied to the burner 26 through the inlet 37, and is mixed with the oxygen- containing gas in front of the burner 26.
• the burner 26 is ignited by means of the ignition element mounted in the tube 28.
• the burner gases flow towards the end wall 3 and thereafter to the gap-like burner gas channel 41, and leave said channel 41 through the outlet 6, where ⁇ after the gases are led away to the generator sur ⁇ roundings.
• a mixture of air and natural gas is supplied to the generator 1, through the inlet 50.
• This gas mixture flows into the space 24 and thereafter through the openings 25 and into the channel 16 defined between the tubular member 12 and the tubular wall 8.
• the gas flows from the channel 16 through the catalytic bed, where the desired process gas mixture is produced.
• the process gas flows from the catalytic bed through the gap 14 and into the space 17, and thereafter through the conduits 18 through the end wall 3.
• the process gases flow towards the disc-shaped element 32 and then propagates in the furnace space.
• the catalytic bed is configured as a cylindrical shell which is heated on both the internal and external surfaces thereof by the burner gases exiting from the burner 26, an even temperature distribution is obtained in the catalytic bed.
• the amount of heat delivered by the burner is controlled with the aid of temperature sensors in the catalytic bed, such that the bed tempera ⁇ ture will lie within a predetermined range.
• Gas samples may be taken from the space 17, for the purpose of monitoring the composition of the process gas and con- trolling the gas components delivered to the inlet 50.
• the reactant-gas supply conduit 16 is embraced externally by an insulator and is cooled internally by cold combustion air supplied to the burner 26, the reactant gas contacting the catalytic bed will be cold. Consequently, the catalyst can be maintained at a higher temperature than would otherwise be the case if hot gas was able to reach the bed. Cooling of the reactant gas will also prevent the gas from decomposing before it reaches the catalyst.

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• Chemical & Material Sciences (AREA)
• Organic Chemistry (AREA)
• Chemical Kinetics & Catalysis (AREA)
• Engineering & Computer Science (AREA)
• Crystallography & Structural Chemistry (AREA)
• Thermal Sciences (AREA)
• Physics & Mathematics (AREA)
• Mechanical Engineering (AREA)
• Materials Engineering (AREA)
• Metallurgy (AREA)
• Devices And Processes Conducted In The Presence Of Fluids And Solid Particles (AREA)
• Physical Or Chemical Processes And Apparatus (AREA)
• Furnace Details (AREA)

Applications Claiming Priority (2)

Publications (1)

Family

ID=20373473

Family Applications (1)

Country Status (3)

Cited By (3)

Citations (4)

• 1988
  • 1988-09-28 SE SE8803446A patent/SE461767B/sv not_active IP Right Cessation
• 1989
  • 1989-09-01 EP EP19890910240 patent/EP0396659A1/de not_active Withdrawn
  • 1989-09-01 WO PCT/SE1989/000458 patent/WO1990003218A1/en not_active Application Discontinuation

Patent Citations (4)

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