DE19606571C2 - Oven with pyrolytic cleaning and method for operating such an oven - Google Patents

Description

The invention relates to an oven according to the Oberbe handle of claim 1 and a method for operating such an oven. So it's one Oven with pyrolytic cleaning, during which The temperature in the baking or cooking space after the output signal of a tem temperature sensor up to that for pyrolytic cleaning sufficient temperature is raised and in which the exhaust gases from the baking or cooking space via a withdrawn at least one-stage catalyst.

Ovens with pyrolytic cleaning are various which embodiments, e.g. B. from DE-AS 23 29 024 and from US 4,831,237 known. For pyrolytic cleaning supply of those contaminated by the baking or cooking process Inner wall surfaces of the oven muffle will be their temperature mostly gradually up to a value of about 500 ° C raised while the oven door is off at the same time safety reasons is locked against opening. At this tem temperature burn the organic pollutants and the Any gases that occur are from the baking or cooking space  withdrawn over an at least one-stage catalyst and can then add almost no odor to the ambient air be mixed. Let the oven muffle cool down the combustion residues as dust-fine white Sweep ash removal in a simple way. The pyro lytic cleaning process therefore makes cleaning easier holding the oven and relieving the user of troubles take and time consuming cleaning work.

In known control methods for the pyrolytic Rei cleaning process, a time control is carried out in this way causes the temperature in the baking or cooking space of the oven muffle by a timer in connection with a Temperature sensor is gradually increased. The total Period of the cleaning process must be manually pre-selected will give. The cleaning result depends on con constant time input also of mains voltage fluctuations as well as mechanical and electrical tolerances of the Components and the device.

From document US 4,954,694 is a generic Known oven with pyrolytic cleaning, in which the Exhaust gases are withdrawn from the cooking space using a catalytic converter become. There is a temperature sensor in the oven and on the A gas sensor is arranged on the outlet side of the catalytic converter net, both to control the pyrolytic Reini be used. The gas sensor is a Pollution sensor measuring the degree of pollution.

The invention is based on the task, one largely independent pyrolytic cleaning agents creating process, each with an opti Male adjustment of the heating a desired cleaning degree should be achieved. This is done according to the invention an oven with the features of claim 1 and by a method with the features of claim 15 he  enough. According to the invention is a further temperature sensor-designed contamination sensor in connection provided with the catalyst. So it's Reini process depending on the output signal of the further temperature sensor and the temperature sensor adjustable. In this way the pyrolytic Reini directly monitored and optimally regulated, see above that manual time entries are no longer necessary.

A contamination sensor can generally be completely different whose way to monitor various the pollution degree of characteristic be, for example as a gas analytical sensor. A he according to the invention designed as a further temperature sensor The contamination sensor can escape from the catalytic converter exhaust gas flow with regard to one for the pollution efficiency characteristic, namely the tem temperature in the exhaust gas flow, monitor. Such a Another temperature sensor determines the temperature of the Air behind the catalytic converter and this output signal is used in conjunction with the output signal of the temperature sensors for regulating the temperature or switching on used for the oven heating elements.

Instead of monitoring the exhaust gas flow from the Kataly sator can be designed as a further temperature sensor Contamination sensor may also be useful State variable of the catalyst itself, for example monitor its infrared radiation or core temperature.

For simplicity, however, in most cases as a pollution sensor in the exhaust gas flow the additional temperature sensor may be appropriate. A direct pollution sensor oriented on the catalytic converter For example, one with a view of the Kataly  sator-directed optical sensor, which the Infrared radiation picks up and becomes an output signal processed.

So that the catalytic converter works even with low emissions required operating temperature can be reached Lich a heating device can be provided, which heated the catalyst until it reached its reak tion with the exhaust gases a desired operating temperature is reached. Such a catalyst can be useful be designed in one or two stages.

Because the fumes from the oven muffle hydrocarbons Contained in different compositions, it can be used Exclusion of an explosion may be appropriate on the Inlet side of the catalyst or the additional heating device to provide explosion protection. This can be advantageous in the form of a close-meshed wire mesh or a perforated plate.

The pollution formed as a further temperature sensor tion sensor is appropriate above the outlet side of the Catalyst arranged at a distance. In addition, the Outlet side with the cooling air flow of the oven in whose housing connected so that the gases from the Pulled off the baking or cooking space over the catalyst and with the general exhaust air flow of the cooling air in the reverse exercise room. For a good effectiveness of the The catalyst speed must not be too high be high. It therefore appears appropriate on the outlet side of the catalyst after a flow restrictor switch on, which be the passage of the catalyst limits. Such a flow restrictor element can possibly advantageous with regard to its throughput zes controllable or regulable and thus in the control loop  be involved. Such a flow restrictor element can expediently in front of the outlet opening of the catalyst brought cover pot, which edge flow Breakthroughs, for example in a circular shape. For the catalyst or for its stages are used moderately perforated ceramic discs used, the Surface and the passage recesses each with a Precious metal, platinum, palladium or the like, coat are.

Appropriate training can provide that the end output signal of the temperature arranged in the cooking or baking chamber ratursensors and the output signal of in the range of Catalyst arranged pollution sensor, which as Another temperature sensor is formed, a micro processor are fed, which signals for control the temperature of the oven radiator provides. The To Set heating device of the catalyst can be used moderately together with at least one catalyst in one outlet connection emerging from the cooking or baking chamber Oven muffle may be arranged.

A convenient method of operating an oven with pyrolytic cleaning can be done in the way be that after turning on the pyrolytic Reini supply process first one from the temperature sensor in the cooking room-controlled temperature increase up to about 300 ° C is carried out, the catalyst through the Zu set heating device brought to working temperature becomes. After that, depending on the output signal the further temperature sensor the heating power of the baking oven heating elements until reaching for clear the pyrolytic cleaning process appropriate temperature increased. This is in the generally at about 500 ° C.

In the drawing is an oven with pyrolytic rice slope according to the invention shown schematically.

One can see in the drawing (cross-section through the baking oven viewed from above) a housing 1 , an electric baking oven in the form of installation, the baking oven muffle being designated by 2 . The oven muffle 2 has a heat-insulating coating made of rock wool, for example 40 mm thick. Through the oven muffle 2 , a baking or cooking space 2 a is formed, which is closed at the front by an oven door 1 a. In a tubular outlet 3 , which is inserted into the rear wall of the oven muffle 2 , there is a two-stage catalyst 4 which is connected upstream of an additional heating device 5 in the form of a tubular heater. The gases drawn off in the flow direction indicated by an arrow flow through the tubular heater. In front of the tubular heater is a close-mesh wire mesh 6 serving as explosion protection.

The exhaust gas flow emerging from the catalyst 4 is monitored by a pollution sensor, which is designed as a further temperature sensor 7 , with regard to the temperature value. The output signal of the further temperature sensor 7 is fed to a control unit 8 , which also processes the output signal of the temperature sensor 9 located in the baking or cooking space.

Two oven heating elements 10 , 11 are heated by the control circuit in the control unit 8 according to the desired temperature increase.

To cool the housing 1 , a cooling air flow flowing between a housing and inlet opening is generated in the housing by a blower, not shown. This cooling air flow is directed in the region of the rear wall of the oven muffle 2 downwards. At the same time, it sucks exhaust air out of the catalyst 4 , mixes it with the cooling air and expels the air mixture into the surrounding space.

To throttle the flow of the catalyst, a cover pot 12 is provided on its outlet side as a flow restricting element, which has flow openings 13 at the edge.

The catalyst 4 is constructed in two stages from perforated noble metal-coated ceramic disks.

Claims (15)

1. oven with pyrolytic cleaning, which is formed from that during the cleaning process, the temperature in the baking or cooking space ( 2 a) after the output signal from a temperature sensor arranged in this ( 9 ) up to that for the pyrolytic cleaning process sufficient temperature can be raised, and which is designed such that the exhaust gases from the baking or cooking space ( 2 a) can be drawn off via an at least single-stage catalyst ( 4 ), and which has a contamination sensor which characterizes the degree of contamination of the oven Condition variable is monitored and arranged in the exhaust pipe, and in which the cleaning process can be regulated as a function of the output signal of this contamination sensor and the temperature sensor ( 9 ), characterized in that the contamination sensor is another, the temperature of the catalyst ( 4 ). temperature sensor, directly or indirectly recording and forwarding for evaluation ( 7 ) is. 2. Baking oven according to claim 1, characterized in that the further temperature sensor ( 7 ) is designed for indirect monitoring of the temperature of the exhaust gas flow emerging from the catalyst ( 4 ). 3. Oven according to claim 1, characterized in that the further temperature sensor ( 7 ) for the direct monitoring of infrared radiation or the core temperature of the catalyst ( 4 ) is formed. 4. The device according to claim 1, characterized in that the catalyst ( 4 ) with an additional heating device ( 5 ) is provided. 5. The device according to claim 4, characterized in that the additional heating device ( 5 ) together with the at least one catalyst ( 4 ) within a tubular from the cooking or baking chamber ( 2 a) of the oven muffle ( 2 ) emerging outlet nozzle ( 3 ) is. 6. The device according to claim 1, characterized in that the catalyst ( 4 ) is designed in two stages. 7. The device according to claim 1, characterized in that an explosion protection ( 6 ) is connected upstream on the inlet side of the catalyst ( 4 ). 8. The device according to claim 7, characterized in that the explosion protection is a close-mesh wire network ( 6 ) or a closely perforated plate. 9. The device according to claim 1, characterized in that the further temperature sensor ( 7 ) is arranged above the outlet side of the catalyst at a distance and that the outlet side is connected to the cooling air flow of the oven in such a way that the gases from the baking or cooking space ( 2 a) are drawn off over the catalyst ( 4 ). 10. The device according to claim 9, characterized in that on the outlet side of the catalyst ( 4 ), a flow throttle element ( 12 ) is connected downstream, which limits the throughput of the catalyst. 11. The device according to claim 10, characterized in that the flow throttle element ( 12 ) is designed to be variable in terms of its throughput. 12. The apparatus according to claim 10, characterized in that the flow restriction element is a cover pot ( 12 ) attached in front of the outlet opening of the catalyst ( 4 ), which has flow openings ( 13 ) on the edge. 13. The apparatus according to claim 1, characterized in that the output signal of the cooking or baking chamber ( 2 ) arranged temperature sensor ( 9 ) and the output signal of the in the region of the catalyst ( 4 ) angeord Neten further temperature sensor ( 7 ) a microprocessor are supplied, which produces signals for regulating the temperature of the oven radiators ( 10 , 11 ). 14. The apparatus according to claim 1, characterized in that the catalyst ( 4 ) is at least one noble metal coated perforated ceramic disc. 15. A method of operating an oven with pyrolytic shear cleaning according to one of the preceding claims, characterized in that after switching on the pyrolytic cleaning process with a temperature sufficient for the pyrolytic cleaning process, temperature first of all from the temperature sensor ( 9 ) in the baking and cooking space ( 2 a) controlled temperature increase is carried out up to about 300 ° C, and that then the temperature in the baking or cooking space ( 2 a) is additionally increased depending on the output signal of the further temperature sensor ( 7 ) up to the temperature sufficient for the pyrolytic cleaning process .