Classifications

• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F24—HEATING; RANGES; VENTILATING
  • F24C—DOMESTIC STOVES OR RANGES ; DETAILS OF DOMESTIC STOVES OR RANGES, OF GENERAL APPLICATION
  • F24C3/00—Stoves or ranges for gaseous fuels
  • F24C3/08—Arrangement or mounting of burners
  • F24C3/085—Arrangement or mounting of burners on ranges
• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F24—HEATING; RANGES; VENTILATING
  • F24C—DOMESTIC STOVES OR RANGES ; DETAILS OF DOMESTIC STOVES OR RANGES, OF GENERAL APPLICATION
  • F24C3/00—Stoves or ranges for gaseous fuels
  • F24C3/12—Arrangement or mounting of control or safety devices
  • F24C3/126—Arrangement or mounting of control or safety devices on ranges
• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F23—COMBUSTION APPARATUS; COMBUSTION PROCESSES
  • F23D—BURNERS
  • F23D2203/00—Gaseous fuel burners
  • F23D2203/10—Flame diffusing means
  • F23D2203/105—Porous plates
• • F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
  • F23—COMBUSTION APPARATUS; COMBUSTION PROCESSES
  • F23D—BURNERS
  • F23D2212/00—Burner material specifications
  • F23D2212/20—Burner material specifications metallic
  • F23D2212/201—Fibres

Definitions

• the present invention relates to a cooking assembly for a stove or hob, of the type comprising a hob and at least one gas burner for heating a container placed above said gas burner.
• Cooking assemblies using electric resistance plates have also been known for a long time, using no
• honeycomb structure possibly honeycomb and / or with surface craters allowing to place the combustion flames in the cells of the ceramic).
• TM in any event limits the possibility of use: ultimately, this path tending to be closer to electrical solutions does not lead to performance equivalent to halogen lamps or induction.
• the object of the invention is to design a cooking assembly, the design of which makes it possible to obtain the main advantages of the most recent electric cooking plate systems, while avoiding the drawbacks of known techniques as regards their inertia and their safety. .
• the object of the invention is also to design a cooking assembly allowing the use of a ceramic glass hob, molded glass, or any other material compatible with technical and aesthetic requirements, such as agglomerates of mineral substances. recently developed, without the risk of excessive heating of said plate and without confinement of atmosphere under it, while retaining a satisfactory and aesthetic appearance.
• a cooking assembly for a stove or hob comprising a cooking plate and at least one gas burner making it possible to heat a container placed above said gas burner, said cooking plate.
• the radiant burner with a fibrous metallic structure is removable for cleaning, the mounting and dismounting of said radiant burner being carried out at least in part by rotation of the latter.
• the radiant burner with a fibrous metallic structure is screwed directly onto the cooking plate, the associated opening then having a thread corresponding to the external thread provided laterally on said radiant burner; . the radiant burner with a fibrous metallic structure is screwed by means of an insert to the cooking plate, the associated opening then being smooth, and said insert having internally a thread corresponding to the external thread provided laterally on said radiant burner; . the radiant burner with a fibrous metallic structure is screwed by its lower portion onto a screwing well secured to the bottom of said assembly, a high temperature resistant seal being provided between the associated opening and the adjacent lateral edge of said radiant burner; .
• the radiant burner with a fibrous metallic structure is connected by a bayonet system or with an inclined ramp to a fixed box arranged under the cooking plate, coaxially with the associated opening; preferably then, the fixed housing forms at the same time the air / gas mixing chamber of the radiant burner with a fibrous metallic structure.
• a helical spring to be associated with the radiant burner with a fibrous metallic structure, by being compressed when said radiant burner is in the operating position, so as to facilitate the emergence of said radiant burner during disassembly thereof.
• the cooking plate has salient reliefs organized around the opening associated with the radiant burner with a fibrous metallic structure to support the container to be heated above the upper face of said radiant burner; in particular, the protruding reliefs are undulations or grooves in one piece with the cooking plate, said cooking plate preferably being made of molded glass or glass-ceramic, or - ** still of a solid material consisting of mineral substances coated with an organic polymer binder.
• the upper face of the radiant burner with a fibrous metallic structure has protruding reliefs for supporting the container to be heated above said upper face.
• the protruding reliefs are grooves, ribs, or the like, or domed studs, which domed studs are integrated into the radiant burner with a fibrous metallic structure or to the support of said radiant burner, or even attached and removable.
• the upper face * ⁇ of the radiant burner with a fibrous metallic structure is in one piece, so that said face constitutes a single radiant surface, active in its entirety.
• the upper face of the radiant burner with a fibrous metallic structure comprises a plurality of disjointed radiant surfaces J flush with the level of the upper face of a common support; in particular, the disjointed radiant surfaces, when viewed from above, have an elongated shape, and are preferably arranged parallel to a common direction.
• the common support closes the opening 25 associated with the radiant burner by covering the edge of said opening, and is connected, preferably by a bayonet system, to a fixed housing arranged under the cooking plate, coaxial with said opening, said fixed box forming an air / gas mixing chamber common to all the disjointed radiant surfaces.
• the aforementioned common support will for example be a metal block, preferably protected externally by a coating.
• each radiant burner metal fiber structure is supplied with air by an associated fan, the air inducing gas necessary for making the mixture through a venturi at - 55 at the neck which is injected gas.
• FIG. 2 illustrates a variant of the previous embodiment, in which the reliefs (for example grooves) are provided on the upper face of the radiant burner with a fibrous metallic structure, the cooking plate can then be flat around the opening associated;
• FIGS 3a to 3c illustrate, on a larger scale, different particular embodiments of the previous cooking assembly, in which the radiant burner is removable, by being screwed onto the cooking plate by means of a insert (Figure 3a), or screwed onto the bottom of the cooking assembly ( Figure 3b), or even connected by a bayonet system to a fixed box placed under the cooking plate, with interposition of a release spring ( Figure 3c);
• FIG. 1 is a more detailed section of the mounting of a radiant burner with metal fibers, with its lower housing forming the associated chamber of air / gas mixture, the upper face of said radiant burner being here in one piece, to constitute a single radiant surface fully active;
• FIG. 5 illustrates in section another variant, in which the upper face of the radiant burner with a fibrous metal structure comprises a plurality of disjointed radiant surfaces flush with the level of the upper face of a common support which is for example a metal block;
• - Figure 6 is a section of the aforementioned common support, and
• Figure 7 is a top view of this common support, showing a set here of thirteen radiant surfaces, elongated and disjoint (Figure 6 being a section along VI-VI in Figure 7);
• Figure 8 is a section of the burner body associated with the aforementioned common support, and Figure 9 is a top view of this burner body (Figure 8 being a section along VIII-VIII of Figure 9);
• FIG. 10 is a diagram illustrating a preferred mode of supply of a radiant burner of the cooking assembly according to the invention, with a
• the cooking assembly for stove or hob which will be described is of the type comprising a cooking plate and at least one gas burner for heating a container placed above said burner, said cooking plate having an associated opening audit * - 'gas burner to allow direct action of said burner through said opening when this burner is used.
• At least one of the gas burners is a radiant burner with a fibrous metallic structure, the upper face of which is essentially flat and is flush with the
• said radiant burner being arranged so as to close the associated opening.
• FIG. 1 there can thus be seen a cooking plate 1 comprising an opening associated with a radiant burner 100 with a fibrous metallic structure, the upper face 10 1 of which here is essentially flat,
• the projecting reliefs 2, 3 can be corrugations or grooves, or alternatively protruding pins, which are preferably in one piece with the cooking plate 1, which is advantageously made of
• molded glass or glass ceramic or a solid material consisting of mineral substances coated with an organic pepper binder, such as the material sold under the brand CORIAN by the company Du Pont de Nemours.
• protruding reliefs may alternatively be provided on the radiant burner itself, which allows on the one hand to preserve the flatness of the hob and therefore facilitate its manufacture in molded glass, glass ceramic, or material agglomerated of mineral substances, and on the other hand to use small containers on large diameter burners.
• FIG. 2 Such a variant is illustrated in FIG. 2, where there are
• the raised reliefs may have a height of a few millimeters, so as not to alter the uniform appearance of the upper face of the
• the flame causes the water to evaporate and any organic products to be burned (self-cleaning by pyrolysis).
• the overflow affects a stationary radiant burner, the 0 liquid products dirty the upper face of this burner. It may then be advantageous to be able to dismantle the burner to wash it more easily (or possibly replace it).
• the radiant burner 100 with a fibrous metallic structure will therefore be removable, and its assembly and disassembly will be carried out at least in part by rotation of the latter.
• the radiant burner 100 with a fibrous metallic structure can be screwed directly onto the cooking plate 1, the associated opening then having a thread corresponding to the external thread provided laterally on said radiant burner.
• This solution (not shown here) is J, however, difficult to implement insofar as obtaining such a thread on a plate of a material such as the ceramic remains delicate: they can then choose one of the solutions illustrated in Figures 3a to 3c.
• the radiant burner 100 is screwed by means of an insert 7 to the cooking plate 1.
• the msert 7, which may be metallic, ceramic, or any other suitable material, is molded or glued to the baking sheet 1. It is here in the form of an L-section ring, internally threaded in correspondence with an external thread provided laterally on the radiant burner 100: the associated opening then has an edge smooth, and it avoids having to make a thread of the cooking plate at the level of said opening.
• the radiant burner 100 has a lower extension 107 externally threaded, for screwing on a tapped well
• the radiant burner 100 is connected by a bayonet or inclined ramp system to a separate piece placed under the cooking plate 1, coaxially with the axis 10 of the associated opening 4.
• the burner 100 is here received in a fixed casing 102 having lugs 103 projecting inward, said lugs being received in associated slots 104 formed at the periphery of the radiant burner 100.
• the slots 104 are essentially horizontal (in part), in accordance with a bayonet type connection, so that it is advantageous to provide a helical spring 106 housed between the bottom 105 of the fixed housing 102 and the lower part of the radiant burner 100, said spring being compressed when said burner is mounted in the operating position.
• a helical spring 106 housed between the bottom 105 of the fixed housing 102 and the lower part of the radiant burner 100, said spring being compressed when said burner is mounted in the operating position.
• the above-mentioned fixed casing can advantageously simultaneously form the air / gas mixing chamber of the radiant burner 100 with a fibrous metallic structure.
• radiant metal fiber burners are very advantageous insofar as a significant part of the energy (20 to 30%) is directly transmitted in radiant form, which considerably improves the efficiency of cooking of such burners, and where the mechanical resistance is very high (especially if the fibers are sintered), which makes it possible to withstand thermal shock (in the event of liquid or solid overflow) and household cleaning (by scraping or otherwise), unlike the perforated ceramic gas burners mentioned above.
• the metal fiber material also has very low thermal inertia due to the conductivity of the fibers and the high porosity. The amount of heat accumulated is small, and it is very easily restored.
• the entire surface in contact with the combustion products should offer the same quality: an insulating coating resistant to high temperature can then constitute an acceptable solution when the fibrous material does not cover all the burner surface. Care should also be taken to "avoid thermal bridges to prevent unfavorable conduction between the combustion surface and the combustion chamber: it will thus be possible to provide additional thermal protection at the peripheral zones which are packed in to ensure fixing of the burner, and possibly also an upstream protection on areas not covered burner mate 'riau • fibr them.
• Such metallic fibrous burners can operate either in radiating mode (surface combustion incandescent carrying the most superficial fibers), or in blue flame mode when the speed of circulation of the air-gas mixture in the porous medium becomes greater than the speed of flame spread of the same mixture. To obtain this operating mode, it is possible either to increase the surface power admitted to the burners, or to decrease the propagation speed by modifying the air / gas ratio. In radiant mode, such burners emit little oxides
• T from a material sold under the brand FECRALLOY of 22 microns in diameter and 4 mm in length, fibers which are randomly arranged parallel to the support plane and then compressed and sintered to provide a material of porosity between 80 and 85%, and extremely low variation in porosity.
• other refractory alloys may be used to make the fibrous material, or certain equivalent ceramic fibers.
• the finished material is then in the form of a layer with a thickness of between I and 4 mm, a thickness of
• FIG. 4 illustrates in more detail a radiant burner 100 with a fibrous metallic structure, which comprises a burner body 150 supporting a thickness of fibrous material in the form of a plate 152 closing the air-gas mixing chamber 151.
• the fibrous metallic layer 152 is fixed to the body 150 by any means, here shown schematically by a crimping ring 153, here in a T-shaped section, one wing of which covers the edge of the opening 4 of the cooking plate 1, with the interposition of a 153 'flat seal, for example in silicone, guaranteeing the flexibility required for mounting and a perfect seal against overflows.
• compression can be used by screwing on the cover, bonding with ceramic glue, riveting, stapling, or screwing.
• a homogenization and distribution device device here schematically in the form of a grid 154, which allows a homogeneous supply over the entire rear face of the plate of fibrous material 152, avoiding the formation of preferential courses. It is also possible to modulate the heating surfaces of the radiant burners used as a function of the power and the size of said burners.
• the radiant burner previously described with reference to FIG. 4 indeed has an upper face 101 in one piece
• plate 1 52 so that said face constitutes a single radiant surface, active in its entirety. It may however prove to be advantageous to divide the radiant surface and to use a plurality of disjointed, smaller radiant surfaces, each forming a burner sub-assembly, as illustrated in FIGS. associated burner body.
• a radiant burner 100 with a fibrous metallic structure the upper face 1 01 of which has a plurality of disjointed radiant surfaces, thanks to plates 1 52 ′ (here thirteen plates) flush with the upper face 101 'of a common support 160.
• the common support 160 has infé ⁇ eurement an edge with projections 165 allowing mounting of the bayonet type on the burner body 150, cooperating with the homologous projections 169 of said body.
• a peripheral groove 167 is provided on the housing body 1 0, to have a seal 168 which ensures, in addition to the gas tightness of the chamber 151, a backlash at the level of the bayonet coupling connection (the seal 168 is slightly compressed during assembly to maintain a spring effect allowing this backlash to be guaranteed).
• the burner body 1 50 made of metal or plastic compatible with the material of the common support (compatibility both thermal and mechanical for the relative sliding), rests by its bottom 166 on the bottom F of the assembly of cooking, possibly with the interposition of a thin fibrous mattress (not shown here) used for thermal insulation and possibly also contributing to backlash.
• the burner body 150 simultaneously defines the chamber 151 of air / gas mixture from the radiant burner, said mixture arriving via a lateral inlet 155, said chamber communicating directly with a lower central space 162 of the common support 160 into which open elongated openings 161 formed in the upper wall of said common support. These elongated openings 161 have a shoulder 163 on the upper side allowing the plates 152 ′ of fiber material to be supported.
• the plates 1 52 ′ are thus flush with the essentially flat upper face 101 ′ of the common support 160, which upper face extends radially by a slightly rounded peripheral edge 101 ′′ covering the edge of the opening 4 of the cooking plate 1.
• the common support 160 is supported on the cooking plate 1 by the lower face 164 of its peripheral edge 101 ", with the interposition of a flat seal 164 'preferably made of silicone , which guarantees both a perfect seal against overflows and flexibility to take up play.
• the air / gas mixture arriving via the inlet duct 1 55 enters the chamber 151 which is thus common to all the disjointed radiant surfaces 152 ′.
• the disjointed radiant surfaces 152 ′ have, in top view, an elongated shape, and are preferably arranged parallel to a common direction A. It goes without saying, however, that it will be possible to use different shapes and / or arrangements for these separate radiant surfaces.
• the common support 160 is for example constituted by a metal block, advantageously coated with an outer protective layer.
• FIG. 10 schematically illustrates a front mode of feeding a radiant burner of the cooking assembly according to the invention.
• a gas supply line 300 is thus distinguished, equipped with a regulator 301, and opening into a venturi 302; the air is supplied by a pipe 304 by means of a fan 303.
• each radiant burner 100 is supplied with air by an associated fan 303, and the air (produced by the associated venturi 302) induced via the venturi at level of the neck thereof the gas necessary for the preparation of the mixture.
• the gas pressure is regulated by the associated regulator 301, which is preferably controlled, by means of a loop 305, thereby the pressure of the air-gas mixture which is finally brought by line 306 to the radiant burner 100.
• the fan control 303 which makes it possible to vary the air flow and therefore the power of the burner, can be done by an associated electric variator: this makes it possible to eliminate the presence of electric or electro-mechanical actuators, and to equip all of cooking sensitive touches.

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• Engineering & Computer Science (AREA)
• Chemical & Material Sciences (AREA)
• Combustion & Propulsion (AREA)
• Mechanical Engineering (AREA)
• General Engineering & Computer Science (AREA)
• Baking, Grill, Roasting (AREA)
• Gas Burners (AREA)
• Cookers (AREA)
• Electric Stoves And Ranges (AREA)

Applications Claiming Priority (3)

Publications (2)

Family

ID=9400799

Family Applications (2)

Family Applications Before (1)

Country Status (9)

Cited By (1)

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• 1919
  • 1919-09-26 US US07/852,243 patent/US5313049A/en not_active Expired - Fee Related
• 1990
  • 1990-10-01 FR FR9012060A patent/FR2667384A1/fr active Granted
• 1991
  • 1991-09-26 EP EP91917312A patent/EP0503038B1/de not_active Expired - Lifetime
  • 1991-09-26 US US07/852,220 patent/US5259361A/en not_active Expired - Fee Related
  • 1991-09-26 WO PCT/FR1991/000753 patent/WO1992006335A1/fr not_active Ceased
  • 1991-09-26 EP EP91917545A patent/EP0504355B1/de not_active Expired - Lifetime
  • 1991-09-26 ES ES91917312T patent/ES2048598T3/es not_active Expired - Lifetime
  • 1991-09-26 AU AU86196/91A patent/AU8619691A/en not_active Abandoned
  • 1991-09-26 JP JP3516226A patent/JPH05503767A/ja active Pending
  • 1991-09-26 AU AU86589/91A patent/AU8658991A/en not_active Abandoned
  • 1991-09-26 ES ES91917545T patent/ES2066478T3/es not_active Expired - Lifetime
  • 1991-09-26 DE DE69105714T patent/DE69105714D1/de not_active Expired - Lifetime
  • 1991-09-26 WO PCT/FR1991/000752 patent/WO1992006334A1/fr not_active Ceased
  • 1991-09-26 JP JP3515779A patent/JPH05503766A/ja active Pending
  • 1991-09-26 AT AT91917545T patent/ATE115268T1/de not_active IP Right Cessation
  • 1991-09-26 DE DE91917312T patent/DE69101054D1/de not_active Expired - Lifetime

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