EP0638771B1 - Gas cooking device with under a continuous cooking area of heat radiation transparent material, like glass-ceramics, placed radiant gas burners - Google Patents

Description

The invention relates to a gas cooking device with at least one gas radiation burner arranged under a continuous cooking surface made of a material which is permeable to heat radiation, such as glass ceramic, glass, ceramic or a similar material, with a burner chamber and a burner plate made of fiber material, with control devices for the gas supply, and with conventional ignition, safety and temperature monitoring devices, with exhaust gas ducts for removing the combustion gases and with a device, in particular a blower, with which additional air is brought to the burner plate.

Gas cooking devices with gas radiant burners and glass ceramic cooktop have been described in numerous embodiments, such. B. in US-PS 3,468,298, DE-OS 26 21 801, US-PS 4,083,355 or in US-PS 4,201,184.
In gas radiation burners, the gas is burned on the surface of a burner plate made of porous ceramic. In the case of a gas cooking device, one or more such gas radiation burners are arranged at a distance below a common glass ceramic plate known per se, a cooking point being defined by each burner on the upper side of the glass ceramic plate becomes. Each individual gas radiation burner is secured with an ignition device and with an ignition fuse against fuel gas flowing out unused. The description of such a burner plate is found, for. B. in EP 01 87 508 A2.

The temperature of the radiating burner plate is between about 900 ° C and 950 ° C depending on the temperature resistance of the material. The maximum amount of gas that can be fed to the burner is limited by design measures so that a maximum operating temperature cannot be exceeded, e.g. B. to protect the material of the burner plate or the hob and also to avoid unnecessary energy losses.

The permissible maximum temperature of glass ceramic cooktops is usually between about 700 ° C and 750 ° C.
Since in pots with unsuitable, especially uneven floors or even when the cooking area is not occupied, high temperatures can reach temperatures of 900 ° C and more within a short period of time, a temperature limiter is provided to protect the glass ceramic plate, by which such excess temperatures can be reliably prevented can.
Such temperature limiters are e.g. B. in DE-OS 26 21 801 or US-PS 4,201,184 described in detail.

For practical use for heating a cooking surface, in addition to a temperature limit, there must also be a regulation or control of the burner output.
Two principles are known for controlling the performance:
According to one, the burner is operated continuously and the amount of gas supplied is reduced or increased in accordance with the required output and according to the other principle the burner is operated in a clocked manner, ie the burner is always operated with the maximum amount of gas and the required output results from the ratio from switch-on time to switch-off time (clock ratio).

DE 33 15 745 C2 discloses a hob with gas-fired burners and with a continuous cooking surface made of glass ceramic or comparable material, with at least two clearly separated cooking zones, each of which is assigned a separate burning point, with a warming zone and with exhaust gas channels for removing the combustion gases and with auxiliary devices, the burning points having combustion chambers, gas mixing chambers, gas mixing devices and regulating devices, and wherein the burning points, the warming zone and the exhaust gas channels at the areas not used for heat transfer to the hob, including all components of the burning points, made of a low-mass and heat-insulating material common to these parts existing component are enclosed.
From this DE 33 15 745 C2 it can also be seen that a nozzle plate can alternatively also be made from silicate fiber material (column 6, line 21/22).

DE 38 44 081 A1 discloses a cooking apparatus with at least one hob consisting of a burner pot inserted into a burner plate, a nozzle plate and a ceramic plate arranged at a distance above the nozzle plate, an intermediate floor being arranged below the burner pot and a space for control below the intermediate floor and / or control and / or monitoring units is formed, and wherein an exhaust gas outlet is set up, a substantially vertical shaft being arranged on the rear side of the cooking apparatus, which can be connected to an outlet duct or is designed as such, and in the room a fan is arranged for the control and / or regulating and / or monitoring units, which primarily sucks cooling air through this space from the front and presses it into the shaft, the shaft being designed as a flow channel so that the primary cooling air is above the Distance between the burners plate and the intermediate floor draws in secondary cooling air and removes the exhaust gas emerging from the space between the burner plate and the ceramic plate.

DE 38 44 081 A1 is based on the object of improving a cooking apparatus of the construction described with regard to the control of the waste heat and thus overall in terms of heat technology.
A fan is used here to remove only the exhaust gas with a relatively high level of equipment.

From US-PS 4,020,821 it is known to use a fan in a gas cooking device with a continuous plate. B. from glass ceramic to position, which also introduces air for a good combustion of the gas.
Here, however, no gas radiation burners with burner plates are used, but burners with an open flame.

GB 2 230 595 A describes a gas cooker with a glass ceramic plate and at least one gas radiation burner arranged close under the plate, each burner having a burner chamber with a large number of individual chambers and a burner plate perforated to match the arrangement of the chambers is made of ceramic, further with a gas supply and a fan device to provide combustion air whenever the burner is working.

Both US Pat. No. 4,020,821 and GB 2 230 595 A show the use of fans or blowers in gas cooking devices with continuous glass ceramic cooktops, but the overall arrangement of the cooking devices is very complicated and complex and therefore accordingly susceptible to practical use and expensive the production.

The object of the present invention is therefore to present a gas cooking device with a new type of gas burner technology, also for different types of gas, such as natural gas or liquid gases, such as propane or butane, which has a high proportion of radiation energy at very low exhaust gas values, and quick response to changes in the burner output at guarantees a large control range and guarantees maximum safety with a simple, compact design and low overall height.

It is a further object of the invention to offer a cooking device which combines the advantages of the gas flame with the ease of cleaning and the attractive appearance of a glass ceramic cooking surface in an ideal manner and, moreover, is inexpensive to manufacture; especially with a minimum of expensive and difficult to dispose of thermal insulation materials and requires minimal maintenance and repair work, also because all components are clearly arranged and easily accessible.

The object of the invention is achieved in that the device with which additional air is sucked in and brought to the burner plate, and the control device for the gas supply are in a separate room in which an overpressure is maintained, and the is connected to the burner chamber and to the outside via gas-tight lines in the area outside of the separated space on its peripheral surfaces, in particular via pipes.

The control device for the gas supply contains a valve block with interchangeable nozzles positioned in the block, with opening diameters from 0.5 mm to 2.0 mm, in particular with 1 mm, which can be exchanged depending on the type of gas.

The control can also be carried out mechanically, pneumatically or hydraulically if this is advantageous in individual cases. The valve block is usually constructed in such a way that the nozzles are all arranged next to one another and emit their gas flows parallel to one another; but it can also be designed so that the gas flows flow out at an angle to one another.

Should it be necessary for spatial reasons, a valve block with e.g. B. 4 nozzles easily in units with z. B. 2 x 2 nozzles or 1 x 2 and 2 x 1 nozzle can be divided.
This is particularly recommended if the lines carrying the gas / air mixture can remain straight in the arrangement of the modules.

In the separated space, the device with which additional air is fed to the burner plate, that is to say, in particular by means of a fan, maintains an excess pressure of at least 0.1 mbar.
The gas-tight lines that connect the separated space to the burner chamber can have different inlet cross-sectional areas, are round, oval or rectangular and are provided with cables, coils and / or also with tapering and constrictions in the area through which the gas flows. Air mixture and to support the Venturi effect.

The center of the inlet openings of a line, which connects the separated space to the burner chamber, is in each case arranged opposite a nozzle opening, with a variably adjustable distance.
The distance between the start of the pipes and the nozzle openings is adjustable in order to be individually adaptable for burners of different sizes and / or different outputs.

In a particularly preferred embodiment, the line carrying the gas / air mixture is provided in the region of the separated space in which the excess pressure is maintained with adaptable, in particular radially arranged, openings as inlet openings for the air.
The line can then start directly at the valve block or in the plane of the nozzle opening.
This ensures defined installation conditions and a constant supply of air.
Advantageously, the inlet openings for the air z. B. by means of a ring sleeve running on a thread of the line or by means of sliding orifices to enlarge or reduce, and are so the air requirement of the particular burner type or the respective burner size to adjust exactly and without effort.
In these embodiments, the lines serve as mixing tubes over their entire length, the inflow of air into the tubes being achieved by the excess pressure and the Venturi effect arising as a result of the gas injection.

The gas flow is injected into the openings of the mixing tubes and entrains the necessary combustion air.
The inlet cross-sectional area of the line for supplying the gas / air mixture is advantageously more than 150 mm ² .

According to another embodiment of the invention, the valve block as part of the control device for the gas supply in the separated space is arranged so that it laterally, by means of its nozzles positioned in the valve block, the gas at an angle of less than 90 ° in openings provided in the line shoots.
Here, the gas is supplied through a "side bullet" and ensures that it impacts the opposite pipe wall for turbulence and thus for a very good premixing of the gas / air mixture.

In a very preferred embodiment, the control device, in particular the valve block, is accessible via a tightly closable service opening, in order to be able to carry out repairs without any problems or to enable the gas nozzles to be installed or removed quickly.

A further advantage of the invention is that the device with which additional air is brought to the burner plate is positioned in the separated space in such a way that it cools in particular the regulating device, but also other heat-sensitive control devices, by means of the air emitted by it.
The blower can also be positioned in the gas cooking device so that the primary cooling air drawn in by the blower must first pass through the control devices below it before it reaches the blower.

In a further advantageous embodiment, the fan, which maintains an overpressure in the separated space, cools the exhaust gases produced during combustion by adding air by means of a bypass.
The exhaust gas temperatures at the outlet of the cooking device are significantly reduced by this fan arrangement. The operational safety of the cooking device and the ease of use are improved.

According to the invention, the fan can additionally cool the housing wall via an air guide system installed in the outer walls of the cooking device. This also leads to an increase in operational safety and ease of use.
In some cases it can also be advantageous to divert part of the air flow generated by the fan under the burner chamber so that it hits the hot underside of the cooking zone. As a result, the top surface temperature of the glass ceramic plate can be influenced and rapid cooling of the hot areas of the plate is possible, in particular after the burner has been switched off.

According to the invention, it is also possible that the gas / air mixture brought through the lines to the burner plate is guided such that it is preheated by the hot exhaust gases.
These measures lead in particular to improved efficiencies and thus also to energy savings.

In a very preferred embodiment according to the invention, the burner plate contains, in particular SiC fibers as the fiber material.

This type of burner has many advantages:
If a combustible gas / air mixture with liquefied gas or natural gas flows through the porous fiber burner plate and is ignited at the top of the burner material, the material becomes raw-hot within a second due to the low thermal mass.
The hot burner surface emits most of the energy at infrared wavelengths; Radiation and conduction through the glass ceramic plate bring the energy to the bottom of the pot.

The European standard EN 30 "Household Cooking Appliances for Gaseous Fuels" specifies the requirements for the safety and usability of such systems. One of the criteria is the parboiling efficiency. With the gas cooking device according to the present invention, parboiling efficiencies of 37% are achieved. These are 44% higher than the limit values specified in EN 30.

Furthermore, emissions of NO _x and CO were measured on the gas cooking appliances according to the invention. The emissions for NO _x and CO are below the limit values of 37 ppm NO _x and 54 ppm for CO (criteria for the "Blue Enger").

The burner plates made of SiC fibers are also environmentally friendly because the raw materials are found in large quantities in nature. The composite material made from these fibers resists oxidation even at high temperatures. With the fiber burner of the invention, life cycle tests over 5000 hours were carried out without any deterioration in burner properties. Even under severe combustion conditions, the burner was started 12,000 times without a change in the material being found.

In addition, no danger to humans from silicon carbide fibers has been reported to date.

The invention will now be explained in more detail with reference to FIGS. 1 to 10 and the associated exemplary embodiments. Show:

Figur 1a

zeigt einen Kochfeldrahmen (1) mit eingebauter Glaskeramik-Kochfläche (2) und einem Abgasaustritt (3),

Figur 1b

einen Isolationsformkörper (4), mit Aussparungen für die Brenner (4a) und die Abgasführung (4b),

Figur 1c

Brennerplatten (5) aus Fasermaterial, die in den Brennerkammern gasdicht eingeklebt sind,

Figur 1d

ein Montageblech (7) für die Brenner (7a) und die Regeleinrichtung (7b) und eine Aussparung (7c) für den Bypass-Schlitz

Figur 1e

ein Doppelwandgehäuse (8) mit dem abgetrennten Raum (9) und ein Luftleitungssystem (10) zur Gehäusekühlung und

Figur 1f

das Bodenblech (11) mit Aussparungen (11a) für die Gebläseansaugung und die Serviceöffnung (11b).

In Figures 1 af, a gas cooking device according to the invention with its essential assemblies is shown in a perspective exploded view:

Figure 1a

shows a hob frame (1) with built-in glass ceramic hob (2) and an exhaust gas outlet (3),

Figure 1b

a molded insulation body (4) with cutouts for the burners (4a) and the exhaust gas duct (4b),

Figure 1c

Burner plates (5) made of fiber material, which are glued gas-tight in the burner chambers,

Figure 1d

a mounting plate (7) for the burners (7a) and the control device (7b) and a recess (7c) for the bypass slot

Figure 1e

a double wall housing (8) with the separated space (9) and an air duct system (10) for cooling the housing and

Figure 1f

the bottom plate (11) with recesses (11a) for the fan suction and the service opening (11b).

In FIGS. 2a and b different types of insulation body geometries (4) with cutouts (4a) for the burners and the exhaust pipes (4b) are to be presented in a perspective view. The insulation bodies are e.g. B. made of vermiculite.

Figure 3a shows schematically a gas cooker according to the invention in top view when the cooktop frame with the continuous glass ceramic cooktop has been removed.

There are 3 gas radiation burners (12) which are connected to the separated space (9) via gas-tight lines (13), here designed as smooth mixing tubes, in which the fan (14), which has an overpressure of 0, 5 mbar generated and part of the control device (15), here a 3-way valve block (15a) with magnetic control and screwed-in gas nozzles (15b) for natural gas.

The fan (14), which brings air from the outside to the burners (12), additionally cools the exhaust gases generated during combustion by means of a bypass (16) and further prevents increased temperatures by means of an air guide system (17) installed on the outer walls of the cooking device the housing wall.
The control device (15) is accessible at any time via a lockable service opening (18) in order to be able to replace the nozzles or to carry out maintenance work.

FIG. 3a further illustrates the guidance of the gas flows in the cooking device; it can be clearly seen that the control device (15) is cooled by the air flow from the fan (14).

FIG. 3b shows a modified arrangement of the 3 gas radiation burners (12), and, as in FIG. 3a, here is the center of the inlet opening of a mixing tube (13) which connects the separated, pressurized space (9) to the burner chamber (6) , arranged with variably adjustable distance. The service opening is not shown here for the sake of clarity.

Figure 3c shows, in contrast to 3a and 3b, a control device (15), each with screwed-in gas nozzles, in which the valve block is divided into 3 individual elements. As a result, the mixing tubes (13) which supply the gas radiation burners (12) with the gas / air mixture can be straight.

In comparison to FIGS. 3a-3c, FIG. 3d shows another arrangement option for the burners (12) and the control devices (15), which are also designed as individual elements.

FIG. 4 shows a section through the gas cooking device according to the invention. Via the gas nozzle (15b) with an opening diameter of 1.0 mm of the magnetically controlled control device (15) with the valve block (15a), a commercially available propane / butane mixture is introduced into the mixing tube (13 ) injected with a pressure of 30 mbar. The separated space (9) is under an overpressure of 0.2 mbar due to the blower, not shown here, which draws in air from the outside. The air also passes through the excess pressure and the so-called Venturi effect into the mixing tube (13), where it is thoroughly swirled and mixed with the gas before the mixture then reaches the burner (12), which according to the invention consists of a burner plate (5) made of fiber material containing SiC fibers and a burner chamber (6).

Furthermore, a glass ceramic cooktop (2) as shown in FIG. B. is under the trademark CERAN of the applicant in the trade, and the arrangement to recognize once the mounting plate (7) for the burner and the control device and on the other hand the molded insulation body (4).

FIG. 5a illustrates a possibility of how the gas / air mixture is adjusted according to the invention, namely via displaceable diaphragms (19) which make it possible to vary the opening possibilities of the openings in the mixing tube (13), which serve as inlet openings for the air. The screens (19) are arranged in the area of the oval mixing tubes (13) here, which is located in the separated space (9).

The mixing tubes (13) can thus start directly on the valve block (15a) of the control device (15).

FIG. 5b shows a further possibility of adjusting the gas / air mixture by the variably adjustable distance between the nozzle (15b) and the mixing tube (13) while

Figure 5c presents the possibility of adjustment via different cross-sectional threads of the mixing tubes (13).

Figure 6 shows a variant of the invention, according to which the gas is injected laterally.
The control device (15) for the gas supply is arranged in such a way that, through its nozzles (15b) positioned in the valve block (15a), it supplies the gas laterally, at an angle of approximately 40 °, into openings (20) in the mixing tube (13). , which are provided here only for the supply air, includes.

The gas / air mixture then reaches the burner (12) very well mixed due to the turbulence triggered on the tube wall.

FIG. 7a illustrates how the gas / air mixture flowing in the mixing tube (13) can be preheated by the hot exhaust gas, which is produced during the combustion, if the molded insulation body (4) is as in

Figure 7b is shown even more clearly, is suitably designed, and has recesses (21) in which the mixing tubes (13) and the hot exhaust air can carry out a heat exchange.

FIG. 8 again shows some essential features of the invention in a perspective view: the blower (14), which draws in air from the outside, and the regulating device (15) for the gas supply are located in a separate space (9) in which an overpressure is maintained is obtained.

Figure 9 shows the position of the reclosable service opening (18) for quickly changing the gas nozzles (15b) of the control device (15).

FIG. 10 shows the dependence of the volume flow on the speed, the assumed power and the static pressure of the blower used.
Due to the optimal design of the system, a coordinated dimensioning of the blower parameters and the Venturi effect leads to improved control behavior of the burners. Possible pressure fluctuations in the gas supply network and resulting changes in the gas / air mixture can be absorbed with a suitable design (required by EN 30).
In other words, if the gas pressure rises above the usual operating pressure, this leads, due to the then increased Venturi effect, to a lower static pressure in the separated space in relation to the usual operating pressure. As a result, the speed of the blower becomes smaller and thus the volume flow delivered increases. The gas to air ratio remains essentially constant.
If the gas pressure falls below the usual operating pressure, this leads to a weaker Venturi effect and thus, in relation to the usual operating pressure, a higher static pressure in the separated room. The speed of the fan increases and the volume flow delivered is smaller. The gas / air mixture remains within tolerable limits.
In both cases, the combustion quality (CO, NO _X ) remains in the favorable range.

• hoher Anteil an Strahlungsenergie
• niedrige Abgaswerte
• schnelles und visuell erkennbares Ansprechen auf Änderungen der Brennerleistung
• großer Regelbereich
• trotz der hohen Oberflächentemperatur (> 800 °C) der Faser-Brennerplatte bleibt die Brennerkammer und der Brennerkammerrand relativ kühl (etwa 50 °C)
• gleichmäßiges helles Glühbild durch den hohen Emissionsgrad (95 %) von SiC
• einfacher, kompakter und kostengünstiger Aufbau mit niedrigen Bauhöhen (etwa 80 mm)
• übersichtliche Anordnung aller Baugruppen
• wartungs- und reparaturfreundlich
• ein Gebläse/Lüfter
     für die Zwangsbelüftung aller Brenner
     für die verschiedenen Kühlaufgaben
• Regeleinrichtung der Brenner ist jederzeit leicht zugänglich
• austauschbare Gasdüsen für verschiedene Gasarten
• einfache Brennkammergeometrie
• verbesserter Wirkungsgrad
• längere Lebensdauer der elektronischen Einrichtungen durch die Kühlung
• Möglichkeit, ohne zusätzliche Gasleitungen auszukommen und dadurch höhere Sicherheit durch Verringerung von gasführenden Bauteilen.

The advantages of the present invention are:

• high proportion of radiation energy
• low emissions
• quick and visually recognizable response to changes in burner output
• large control range
• Despite the high surface temperature (> 800 ° C) of the fiber burner plate, the burner chamber and the edge of the burner chamber remain relatively cool (approx. 50 ° C)
• Uniform bright glow pattern due to the high emissivity (95%) of SiC
• simple, compact and inexpensive construction with low heights (approx. 80 mm)
• clear arrangement of all assemblies
• easy to maintain and repair
• a blower / fan
  for the forced ventilation of all burners
  for the various cooling tasks
• The burner control unit is easily accessible at all times
• interchangeable gas nozzles for different types of gas
• simple combustion chamber geometry
• improved efficiency
• longer life of the electronic devices due to the cooling
• Possibility of getting by without additional gas lines and thus greater security by reducing gas-carrying components.

Claims (10)

1. Gas cooking appliance having at least one radiant gas burner comprising a burner chamber and a burner plate of fibre material arranged under a continuous cooking surface made of a material transparent to heat radiation, for example glass ceramic, glass, ceramic or a similar material, the appliance being provided with regulating devices (15) for the supply of gas, with customary ignition, safety and temperature monitoring devices, with waste gas channels for the discharge of the combustion gases, and with a device, in particular a blower, by means of which additional air is brought to the burner plate, where the device which draws in additional air from outside and supplies it to the burner plate, and the regulating device for the supply of gas, are located in a separate space in which superatmospheric pressure is maintained and which is connected to the burner chamber and to the outside by means of lines which are gastight on their circumferential surfaces in the region outside the separate space, in particular via pipes, characterized in that the regulating device (15) for the supply of gas comprises a valve block (15a), in particular one having magnetic control, in which block (15a) are positioned interchangable nozzles (15b) having orifice diameters of from 0.5 mm to 2.0 mm, in particular 1 mm, which can be matched to various types of gas.
2. Gas cooking appliance according to Claim 1, characterized in that the gastight lines (13) have various inlet cross-sectional areas, are round, oval or rectangular in shape and are provided with grooves or helices and/or with tapers and constrictions in the region through which flow occurs.
3. Gas cooking appliance according to Claims 1 and 2, characterized in that the middle of the inlet orifice of a line (13) which connects the separate space (9) to the burner chamber (6) is in each case arranged opposite a nozzle orifice at a variably adjustable distance therefrom.
4. Gas cooking appliance according to Claims 1 to 3, characterized in that the line (13) is provided in the region of the separate space (9) with matchable, in particular radially arranged, openings as inlet orifices for the air and begins, in particular, immediately at the valve block (15a) or in the plane of the nozzle orifice.
5. Gas cooking appliance according to Claims 1 to 4, characterized in that the lines (13) serve, over their entire length, as mixing pipes for air and gas, with the air inflow into the pipes being achieved by means of the superatmospheric pressure and the venturi effect occurring as a result of the injection of gas.
6. Gas cooking appliance according to Claims 1 to 5, characterized in that the inlet cross-sectional area of the line (13) for the supply of the gas/air mixture is at least 150 mm².
7. Gas cooking appliance according to Claims 1 and 2, characterized in that the valve block (15a) is arranged in the separate space (9) as part of the regulating device (15) for the supply of gas in such a way that, by means of its nozzles (15b) positioned in the valve block (15a) it injects the gas laterally at an angle of less than 90°C into orifices (20) which are provided in the line (13).
8. Gas cooking appliance according to Claims 1 to 7 where the device is a blower (14), characterized in that the blower (14) additionally cools the wall of the housing via an air conduction system (17) installed in the outer walls of the cooking appliance.
9. Gas cooking appliance according to Claims 1 to 8, characterized in that the gas/air mixture brought to the burner plate (12) through the lines (13) is conducted in such a way that it is preheated by the hot waste gases.
10. Gas cooking appliance according to Claims 1 to 9, characterized in that the burner plate (5) contains SiC fibres.

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