The invention proposes a method for the flame signal detection by means of an ionization electrode (15) protruding into a combustion zone of a burner, comprising the steps: detecting a first signal, which is dependent on an ionization current flowing off the ionization electrode (15), generating a second signal which has a predetermined periodic course, generating a third signal by adding the first signal and the second signal, comparing the third signal with a first threshold value and generating a fourth signal on the basis of the comparison of the third signal with the first threshold value, comparing the third signal with a second threshold value different from the first threshold value and generating a fourth signal on the basis of the comparison of the third signal with the second threshold value, and determining an operating variable of the burner on the basis of at least one of the fourth signal and the fifth signal. The invention additionally proposes a corresponding device for the flame signal detection.

A heat transfer sensor includes a support body, a first thermocouple probe, a second thermocouple probe, and a third thermocouple probe. Each thermocouple probe is mounted to the support body and includes a hollow cylinder, a thermocouple, and an insulator. The thermocouple is mounted to an interior of the associated hollow cylinder and is configured to generate a first voltage based on a temperature of the associated hollow cylinder. The insulator is mounted between the associated hollow cylinder and the top wall. The first hollow cylinder has an emissivity 0.25. The second hollow cylinder has an emissivity 0.75. The third thermocouple probe has an emissivity that is >0.25 and <0.75 or measures a temperature of an environment surrounding the support body. A convective heat transfer and an incident radiation are computed using the first and second voltage and either the third voltage or the air temperature.

The invention proposes a method for the flame signal detection by means of an ionization electrode (15) protruding into a combustion zone of a burner, comprising the steps: detecting a first signal, which is dependent on an ionization current flowing off the ionization electrode (15), generating a second signal which has a predetermined periodic course, generating a third signal by adding the first signal and the second signal, comparing the third signal with a first threshold value and generating a fourth signal on the basis of the comparison of the third signal with the first threshold value, comparing the third signal with a second threshold value different from the first threshold value and generating a fourth signal on the basis of the comparison of the third signal with the second threshold value, and determining an operating variable of the burner on the basis of at least one of the fourth signal and the fifth signal. The invention additionally proposes a corresponding device for the flame signal detection.

A heat transfer sensor includes a support body, a first thermocouple probe, a second thermocouple probe, and a third thermocouple probe. Each thermocouple probe is mounted to the support body and includes a hollow cylinder, a thermocouple, and an insulator. The thermocouple is mounted to an interior of the associated hollow cylinder and is configured to generate a first voltage based on a temperature of the associated hollow cylinder. The insulator is mounted between the associated hollow cylinder and the top wall. The first hollow cylinder has an emissivity 0.25. The second hollow cylinder has an emissivity 0.75. The third thermocouple probe has an emissivity that is >0.25 and <0.75 or measures a temperature of an environment surrounding the support body. A convective heat transfer and an incident radiation are computed using the first and second voltage and either the third voltage or the air temperature.

A combustor including: a combustor case defining a plurality of case apertures; a liner within the combustor case defining a combustion zone and liner apertures through which an airflow flows into the combustion zone; a fuel injector having a fuel channel extending through a first case aperture and the liner, and the fuel channel has a nozzle at the combustion zone through which fuel is injected; an igniter for igniting the combustible mixture of fuel and airflow and providing a flame at the nozzle; and a flame sensor including: a radio frequency transponder, comprising a transmitter-receiver pair, located exterior to the combustor case; a horn antenna disposed in the fuel nozzle, and a tubular waveguide extending from the radio frequency transponder to the horn via one of the plurality of case apertures, wherein the flame sensor is configured to perform flame and flow field diagnostics.