JPH0783803A - Breakage detecting device for ceramic turbine rotor - Google Patents

Abstract

PURPOSE:To detect the breakage of a rotor with good responsiveness by converting the amplitude in a specific wavelength band of the light emitted from a ceramic turbine rotor just before breakage into energy quantity, and detecting the luminous phenomenon as a temperature change. CONSTITUTION:A pyrometer 7 is arranged as a radiation thermometer in the position opposed to a reinforced quarts glass window 5 provided on a bulkhead 6 opposed to a ceramic turbine rotor 1, infrared rays in a wavelength band of 0.25-3mum, particularly, of about 1mum are caught at ultrasonic speed through an optical fiber, and the amplitude of the light is converted into energy (current value), and outputted as the temperature of the rotor 1 to a data processing device 9. Since the luminous phenomenon of the rotor 1 is detected as a temperature change, the luminous phenomenon just before the breakage can be clearly detected even for the rotor 1 incandescently emitting by a high temperature in a hot spin test. Whether the incandescent emission by combustion gas or the emission just before the breakage of the rotor 1 can be clearly discriminated, and the breakage of the rotor 1 can be surely detected with good responsiveness.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a destruction detecting device for a ceramic turbine rotor.

[0002]

2. Description of the Related Art In a gas turbine, air compressed by a compressor is heated by a heat exchanger, and then mixed and burned with fuel in a combustor and blown as high-temperature combustion gas to a turbine rotor to rotate at high speed. This is a device that takes out its power to the outside through the output shaft, and in principle, there is an advantage that there are no major restrictions on the properties of the fuel because continuous combustion is possible. It is expected to improve the thermal efficiency.

Here, as a method of inspecting the durability of the ceramic turbine rotor and studying the mechanism of destruction,
Conventionally, a cold spin test and a hot spin test are performed.

The cold spin test is a test in which only the ceramic turbine rotor is rotated in the vacuum chamber without blowing the combustion gas, and the hot spin test is performed by actually blowing the combustion gas to the ceramic turbine rotor. This is a test in which a ceramic turbine rotor is rotated at a high speed. The cold spin test is performed in a vacuum chamber because the ceramic turbine rotor does not rotate at high speed in air.

Conventionally, in the cold spin test,
Utilizing the phenomenon that the ceramic emits light immediately before it is destroyed by high stress, the photodetector such as a photodiode detects the emitted light, and a high-speed camera photographs the mechanism of destruction of the ceramic turbine rotor.

[0006]

However, in the hot spin test, since the combustion gas is actually blown to the ceramic turbine rotor, the ceramic turbine rotor always emits incandescent light. Therefore, in the hot spin test, whether the ceramic turbine rotor is a light emission phenomenon just before it is broken due to high stress, or is the ceramic turbine rotor emitting incandescent light because it is blown with combustion gas and is simply high temperature? It was difficult to identify.

Therefore, in the hot spin test, an attempt is made to detect the moment of destruction of the ceramic turbine rotor by detecting the light emission phenomenon of the ceramic, but it was difficult to accurately grasp the moment of destruction (actual application: 3-29
760). The present invention has been made in view of the above-mentioned prior art, in the hot spin test, rather than detecting the light emission phenomenon immediately before the destruction of the ceramic as a light emission phenomenon, by detecting the light emission phenomenon as a temperature change,
An object of the present invention is to provide a destruction detecting device for a ceramic turbine rotor capable of detecting destruction with good responsiveness.

[0008]

The first constitution of the present invention for attaining the above object is to convert the amplitude amount of the light emitted from the ceramic turbine rotor immediately before destruction in a specific wavelength range into an energy amount, A radiation thermometer for detecting the temperature of the ceramic turbine rotor at an ultra-high speed, a combustor for blowing combustion gas to the ceramic turbine rotor, and the temperature detected by the radiation thermometer exceeds an upper limit value, And a data processing device for making an emergency stop of the combustor.

The second structure of the present invention which achieves the above-mentioned object is to convert the amplitude amount of the light emitted from the ceramic turbine rotor immediately before destruction in a specific wavelength range into an energy amount so that the temperature of the ceramic turbine rotor becomes super high. A radiation thermometer that detects at high speed, a high-speed camera that photographs the ceramic turbine rotor, and a picture of the ceramic turbine rotor by the high-speed camera when the temperature detected by the radiation thermometer exceeds an upper limit value. And a trigger device for triggering.

[0010]

In the hot spin test, the ceramic turbine rotor emits incandescent light due to the combustion gas from the combustor, and also causes a light emission phenomenon immediately before it is destroyed by high stress. Since the radiation thermometer converts the amplitude of the emitted light into the amount of energy, it can catch the light emission phenomenon as a temperature change.Therefore, whether the combustion gas from the combustor emits incandescent light or high stress Thus, it is possible to clearly distinguish and detect whether the light emission phenomenon is immediately before destruction.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below in detail with reference to the embodiments shown in the drawings. FIG. 1 shows a first embodiment of the present invention. As shown in the figure, in the test device for performing the hot spin test of the ceramic turbine rotor,
The ceramic turbine rotor 1 is rotatably supported.
Alternatively, a power absorbing compressor impeller (not shown) is provided on the other end side.

A combustor 2 is provided upstream of the ceramic turbine rotor 1 and the combustion gas from the combustor 2 is blown to the ceramic turbine rotor 1 to rotate the ceramic turbine rotor 1 at high speed. A fuel supply pipe 3 for supplying fuel is connected to the combustor 2.
A fuel cutoff valve 4 is provided alongside the fuel supply pipe 3.

Further, the partition wall 6 facing the ceramic turbine rotor 1 is provided with a reinforced quartz glass window 5, and a pyrometer (trade name) 7 as a radiation thermometer is provided facing the reinforced quartz glass window 5. . The radiation thermometer converts the amplitude amount of light emitted from the ceramic turbine rotor 1 into an energy amount, and detects it as the temperature of the ceramic turbine rotor 1. The detected temperature measurement signal is output to the data processing device 9.

The pyrometer 7 of this embodiment uses infrared light in the wavelength band of 0.25 to 3 μm, particularly 1
Light of about μm is captured at ultra-high speed, the amplitude of the light is converted into energy (current value), and detected as temperature. Therefore, the light emission phenomenon just before the ceramic is broken due to the high stress can be reliably detected as a temperature change. On the other hand, the shaft portion of the ceramic turbine rotor 1 is provided with a vibration sensor 8 for detecting vibration. Vibration sensor 8
The shaft vibration value signal detected by is output to the data processing device 9.

The data processing device 9 sets the primary stop condition when the temperature detected by the pyrometer 7 exceeds the upper limit value, and the secondary stop condition when the speed of the vibration increase caused by the vibration sensor 8 at the time of destruction exceeds the upper limit value. As a stop condition, the primary,
When the secondary stop condition is satisfied, a combustion stop signal is output to the fuel cutoff valve 4 to close the valve and perform an emergency stop. As an upper limit of the temperature for satisfying the primary condition, for example, a temperature higher by 50 to 100 ° C. than the steady state can be set.

In the destruction detecting device of the present embodiment having the above-mentioned structure, the light emission phenomenon is detected by the pyrometer 7 as a temperature change. , The light emission phenomenon just before the destruction can be clearly understood. That is, in the hot spin test, the ceramic turbine rotor 1 is blown with combustion gas,
Since it emits incandescent light, it is difficult to distinguish it from the light emission phenomenon immediately before the destruction.

However, in the present embodiment, the pyrometer 7 converts the amplitude of light into energy and catches the light emission phenomenon as a temperature change. Therefore, whether the combustion gas from the combustor 2 simply emits incandescent light, Alternatively, it is possible to clearly distinguish whether the light emitting phenomenon occurs immediately before the ceramic turbine rotor 1 is destroyed. In addition, the pyrometer 7 of the present embodiment has excellent responsiveness as compared with the case of detecting a light emitting phenomenon itself which is visible light such as a photodiode and a photomultiplier, and therefore, it is possible to reliably perform the destruction detection. It is safe and there is no danger of catching fire on the lubricating oil.

In the above embodiment, the pyrometer 7 and the vibration sensor 8 are used together, and when the primary and secondary stop conditions are satisfied, the data processing device 9 sends a combustion stop signal to the fuel cutoff valve 4.
However, the vibration sensor 8 can be omitted if it is not necessary.

FIG. 2 shows a second embodiment of the present invention. As shown in the figure, in the test apparatus for performing the hot spin test of the ceramic turbine rotor, the ceramic turbine rotor 11 is rotatably supported, and a compressor impeller (not shown) is provided at the other end side and the output is provided. It is connected to the shaft. Ceramic turbine rotor 1
1, a combustor 12 is provided side by side, and the combustion gas from the combustor 2 is blown to the ceramic turbine rotor 11, so that the ceramic turbine rotor 11 rotates at high speed.

Further, the partition wall 13 facing the ceramic turbine rotor 11 is provided with two reinforced quartz glass windows 14, and a pyrometer (trade name) 15 as a radiation thermometer as a radiation thermometer facing the reinforced quartz glass window 14 and high speed. A camera 16 is provided. This radiation thermometer converts the amplitude amount of light emitted from the ceramic turbine rotor 11 into an energy amount and detects it as the temperature of the ceramic turbine rotor 11. The detected temperature measurement signal is output to the trigger device 17.

The pyrometer 15 of this embodiment is 0.25.
Infrared light in a wavelength band of ˜3 μm, particularly light of about 1 μm is captured at an extremely high speed through an optical fiber, and the amplitude of the light is converted into energy (current value) and detected as temperature. Therefore, the phenomenon that the ceramic emits light immediately before it is destroyed due to high stress can be reliably detected as a temperature change.

As the high speed camera 16, for example, a camera capable of photographing tens of thousands of frames per second can be used. The trigger device 17 triggers when the temperature detected by the pyrometer 7 exceeds the upper limit value, outputs a photographing command signal to the high-sensitivity camera 16, and causes the ceramic turbine rotor 11 to photograph. As the upper limit,
For example, the temperature may be about 50 to 100 ° C. higher than the steady state.

In the destruction detecting device of this embodiment having the above-mentioned structure, since the light emission phenomenon is detected as the temperature change by the pyrometer 15, even the ceramic turbine rotor 11 which emits incandescent light due to the high temperature in the hot spin test. The light emission phenomenon immediately before the destruction can be clearly captured, and therefore, the mechanism of destruction of the ceramic turbine rotor 11 in the high temperature gas can be reliably photographed.

The above embodiment is an example applied to a hot spin test, but the present invention is not limited to this, and a cold spin test, a high temperature turbine test, a bench test corresponding to an actual engine, and a turbocharger are used. It can be widely used for rotor spin tests and the like.

[0025]

As described above in detail with reference to the embodiments, the present invention does not detect the light emitting phenomenon immediately before the destruction of the ceramic as the light emitting phenomenon in the hot spin test, but changes the light emitting phenomenon with temperature. By detecting as, it is possible to detect the destruction with good responsiveness.

[Brief description of drawings]

FIG. 1 is a configuration diagram of a breakage detection device according to a first embodiment of the present invention.

FIG. 2 is a configuration diagram of a breakage detection device according to a second embodiment of the present invention.

[Explanation of symbols]

 1,11 Ceramic turbine rotor 2,12 Combustor 3 Fuel supply pipe 4 Fuel cutoff valve 5,14 Reinforced quartz glass window 6,13 Partition wall 7,15 Pyrometer 8 Vibration sensor 9 Data processing device 16 High sensitivity camera 17 Trigger device

Claims (2)

[Claims] 1. A radiation thermometer for converting an amplitude amount of light emitted from a ceramic turbine rotor immediately before destruction in a specific wavelength range into an energy amount and detecting the temperature of the ceramic turbine rotor at an ultrahigh speed, and the ceramic. A ceramic comprising a combustor for blowing combustion gas to a turbine rotor, and a data processing device for emergency stop of the combustor on condition that the temperature detected by the radiation thermometer exceeds an upper limit value. Destruction detection device for turbine rotor. 2. A radiation thermometer for converting an amplitude amount of light emitted from a ceramic turbine rotor immediately before destruction in a specific wavelength range into an energy amount and detecting the temperature of the ceramic turbine rotor at an ultra-high speed, and the ceramic. A high speed camera for photographing the turbine rotor; and a trigger device for photographing the ceramic turbine rotor by the high speed camera when the temperature detected by the radiation thermometer exceeds an upper limit value. Ceramic turbine rotor breakage detection device.