JP2000088654A - Method for measuring temperature of combustion gas by radiation thermometer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To measure the temperature of combustion gas at a target high temperature section in a furnace using a radiation thermometer by eliminating emission reabsorption phenomenon of combustion gas at a high temperature section caused by low temperature gas in a nozzle. SOLUTION: When the temperature of combustion gas in a furnace 10 is measured using a radiation thermometer 5 disposed on the outside through a window 6 provided at the outer end of a nozzle 4 projecting from a furnace body 7, low temperature gas in the nozzle 4 is purged from the vicinity of the window 6 by means of an optically inert gas A.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a furnace whose temperature is raised by burning combustibles therein, for example, fossil fuels (heavy oil, kerosene, natural gas, propane gas) or wastes (from homes and offices). Power furnace, incinerator, melting furnace that burns municipal waste such as municipal solid waste, waste plastic, car shredder dust, waste office equipment, electronic equipment, industrial waste such as cosmetics, etc. The present invention relates to a method for measuring the temperature of combustion gas in a furnace.

[0002]

2. Description of the Related Art Combustion control in power furnaces, incinerators, melting furnaces, and the like for burning combustion products such as fossil fuels and wastes is often performed by temperature measurement using thermocouples from the viewpoint of emphasis on economy. It is done based on. However, temperature measurement using a thermocouple, which is a contact-type temperature measurement method, has two major problems. One is that the protective tube of the thermocouple is severely corroded and worn by the molten slag when the combustion gas temperature is extremely high. In the situation where is lower than the combustion gas temperature, the thermocouple is affected by the radiant cooling by the inner wall of the furnace, so that the thermocouple indicates a temperature lower than the true combustion gas temperature.

[0003] In the former case, frequent replacement of the protection tube causes an increase in running cost. In the latter case, not only will an incorrect temperature estimation be obtained, but also an accurate calculation of the heat balance of the furnace will be hindered. On the other hand, the measurement of combustion gas temperature using a radiation thermometer, which is a so-called non-contact temperature measurement method for detecting infrared radiation energy from an object to be measured, does not have the above-described problems. In addition, in the temperature measurement by the radiation thermometer, the response of the temperature display is much better than the temperature measurement by the thermocouple.

[0004] Therefore, it is highly useful for controlling power furnaces, incinerators, melting furnaces, and the like that require a quick response. For example, in a gas turbine provided with a moving blade having a ceramic jacket attached to an outer surface of a metal blade axis,
A radiation thermometer is provided at or near the moving blade at the turbine inlet position, the pre-start temperature at this position is measured, the required warm-up operation time according to this temperature state is calculated, and the required warm-up operation is performed. By setting a heating schedule based on time, an increase in the difference in thermal expansion between the metal top cover and the ceramic jacket is suppressed, and the ceramic jacket is prevented from being damaged (Japanese Unexamined Patent Publication No. Hei. 213626).

In an incinerator for municipal solid waste, two radiation thermometers, ie, one having an apparent emissivity in the 4.3 μm band wavelength range, of “1” at a position where a flame of an incineration object can be detected. Another example is a radiation thermometer that measures carbon dioxide (CO ₂ ) in a flame, which is known to become a "flame". Hydrocarbon (HC) in a flame that emits radiant energy in a 3.3 μm band wavelength range A method is known in which a radiation thermometer is installed to measure the combustion temperature of the flame with the former radiation thermometer, and the presence or absence of hydrocarbons, which are unburned gas components, with the latter radiation thermometer. (See JP-A-6-193847).

According to this method, the production of carbon monoxide (CO) or dioxin is suppressed by detecting not only the combustion state of the incinerated material but also whether the air supply amount is excessive or insufficient. can do.

[0007]

However, when a radiation thermometer is used for measuring the temperature of combustion gas, there are the following problems. That is, the temperature of the combustion gas displayed on the radiation thermometer is an average value of the temperature of the combustion gas existing in the optical path. Therefore, it is not suitable for temperature measurement when the temperature distribution in the optical path is wide.

[0008] For example, it is installed outside of the viewing window through a viewing window provided at an outer end of a nozzle protruding from a furnace body of a furnace whose temperature rises by burning combustible materials inside. This is the case when the temperature of the combustion gas in the furnace is measured by a radiation thermometer. The viewing window material used here is corundum (sapphire)
(Al ₂ O ₃ ), calcium fluoride (CaF ₂ ), barium fluoride (BaF ₂ ) and the like are suitable. This is because these window materials hardly absorb the radiated infrared rays from the combustion gas. In the case of quartz glass, 2.5 μm
Since light having a wavelength longer than m is absorbed, it is not suitable for measuring the temperature of combustion gas.

By the way, it is extremely difficult to measure the combustion gas temperature with a radiation thermometer by installing the viewing window near the furnace wall instead of at the outer end of the nozzle. This is because dust, slag melt, and the like frequently adhere to the observation window on the furnace wall surface, and the display of the radiation thermometer decreases due to lack of visual field. Further, the temperature to which the viewing window is exposed becomes extremely high, and damage to the viewing window is significantly increased due to a synergistic effect with the slag melt.

[0010] In this respect, by disposing the viewing window at the outer end of the nozzle, the field of view of the radiation thermometer can be secured and the temperature to which the viewing window is exposed can be kept low, thereby avoiding the above-mentioned problems. You can do it. However,
The presence of the nozzle is a major factor in lowering the temperature display of the radiation thermometer. It is for the following reasons.

That is, the gas existing in the nozzle includes:
There is a temperature gradient from near ambient temperature to near furnace wall temperature. At this time, the low-temperature gas present in the nozzle reabsorbs light emission from the high-temperature combustion gas in the furnace, so the temperature display of the radiation thermometer is significantly lower than the temperature of the combustion gas in the furnace that should be measured. It is because it becomes. The object of the present invention is to
When measuring the temperature of the combustion gas in the furnace using a radiation thermometer, the phenomenon of reabsorption of the luminescence of the combustion gas in the high-temperature part due to the low-temperature gas in the nozzle is removed, and the combustion gas in the high-temperature part in the target furnace is removed. It is to enable temperature measurement.

[0012]

According to a first aspect of the present invention, there is provided a furnace in which the temperature of combustion gas is increased by burning a combustible material therein. Through a viewing window provided at the outer end of the more protruding nozzle, when measuring with a radiation thermometer installed outside the viewing window, a low-temperature gas near the viewing window in the nozzle is removed. This is a method for measuring the temperature of a combustion gas using a radiation thermometer, wherein the temperature is removed by an optical inert gas.

The optically inert gas used here does not contain any component which absorbs in the wavelength region of the emitted light from the component molecules in the combustion gas detected by the radiation thermometer, or a gas having a content as small as possible. It is good to use. According to this measurement method, the low-temperature gas present in the nozzle is driven out by the optical inert gas, and the phenomenon of re-absorption of the emission of the combustion gas in the high-temperature portion by the low-temperature gas is removed, thereby enabling the high-temperature combustion in the furnace The emission from the gas can be detected without attenuating, and the true combustion gas temperature in the furnace can be obtained.

[0014] The invention described in claim 2 is the first invention.
In the invention described above, argon, nitrogen, oxygen, water vapor, air, or a mixed gas thereof is used as the optically inert gas used.
In a general furnace, the combustibles to be burned are mostly carbon-containing substances, and the combustion gas necessarily contains carbon dioxide (CO ₂ ) and / or carbon monoxide (CO).
Are included. For this reason, a radiation thermometer that measures the wavelength of CO ₂ and / or the molecular vibration of CO (for example, 4.3 μm, 4.9 μm, respectively) is used as a radiation thermometer for measuring the combustion gas temperature.

On the other hand, argon, nitrogen, oxygen, water vapor, and air have little or no absorption in these wavelength ranges, and are suitable as optically inert gases. Among them, air contains about 0.03 vol% of carbon dioxide (CO ₂ ), but the measurement error due to the absorption is small in practical use. Air is a very advantageous optical inert gas because it is the cheapest to apply.

[0016] The invention according to claim 3 provides the invention according to claim 1.
Or the optical inert gas is introduced into the nozzle in an amount of 2.0 × 10 ² mm / s or more and 5.0 × 1 or more.
A low-temperature gas in the nozzle is expelled by injecting the gas near the viewing window in the nozzle at a flow rate of less than 0 ³ mm / s. If the flow rate of the optically inert gas in the nozzle is less than 2.0 × 10 ² mm / s, the low-temperature gas in the nozzle cannot be sufficiently removed, and the display temperature cannot be reduced. Conversely, 5.0 × 10 ³ mm
If it is not less than / s, there is an effect of cooling down to the combustion gas to be measured, and in this case, a decrease in the display temperature is inevitable.

Therefore, the flow rate of the optically inert gas in the nozzle is set to 2.0 × 10 ² mm / s or more and 5.0 × 10 ³ m / s.
By installing a device capable of adjusting the flow rate to less than m / s, an environment is created in which the low-temperature gas in the nozzle is expelled and the high-temperature combustion gas in the furnace is not expelled, and a decrease in the display temperature can be avoided.

[0018]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic diagram showing an example of a combustion gas temperature measuring device applied to the embodiment of the present invention. The combustion gas temperature measuring device 9 measures the temperature of the combustion gas in the furnace 10 through a viewing window 6 provided at the outer end (front side) of the cylindrical nozzle 4 protruding from the furnace wall 7. Viewing window 6
The measurement is performed by a radiation thermometer 5 installed outside (in front of).

Further, a gas inlet 11 is provided at the most front side of the nozzle 4, and when the optically inert gas A of the gas cylinder 1 flows into the nozzle 4 from the gas inlet 11, the nozzle Optical inert gas A flowing into 4
Thereby, the low temperature gas in the nozzle 4 is driven out of the nozzle 4. A pressure control valve 2 and a flow meter 3 are provided in a pipe 8 which connects the gas inlet 11 to the gas cylinder 1, and the optical inert gas A supplied into the nozzle 4 is supplied to a predetermined position. The flow rate is controlled so as to be attained.

[0020]

EXAMPLE 1 Using the apparatus shown in FIG. 1, air, which is an optically inert gas A, was flowed through the nozzle 4 to expel the low-temperature gas cooled in the nozzle 4. When the flow velocity of the purge air was gradually increased, the display temperature of the radiation thermometer became maximum (1620 ° C.) when the air velocity in the nozzle 4 exceeded 2.0 × 10 ² mm / s, and thereafter, for a while , And remained at the indicated temperature. When the air flow velocity in the nozzle 4 is further increased to 5.0 × 10 ³ mm / s,
The displayed temperature began to drop. The radiation thermometer 5 used in this test detects infrared light having a wavelength of 4.3 μm, which is one of the radiation infrared rays of CO ₂ molecules.

Example 2 The same temperature measurement as in Example 1 was performed by flowing argon and nitrogen instead of air as the optically inactive purge gas A, but the display temperature between each gas (1630) ° C).

(Comparative Example) Using the same apparatus as in Example 1,
When the same temperature measurement was performed without flowing the purge gas,
The indicated temperature of the radiation thermometer was 690 ° C.

[0023]

As described above, according to the present invention, a furnace using a radiation thermometer in a power furnace, an incinerator, a melting furnace, etc., in which combustible materials such as fossil fuels and wastes are burned inside. The measurement of the combustion gas temperature in the inside can be performed more accurately.

[Brief description of the drawings]

FIG. 1 is a schematic diagram showing an example of a combustion gas temperature measuring device applied to the implementation of the method of the present invention.

[Explanation of symbols]

 A optical inert gas 4 nozzle 5 radiation thermometer 6 viewing window 7 furnace body 10 furnace interior 11 gas inlet

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Ken Miyaji 1 Yawata Kaigandori, Ichihara City, Chiba Prefecture Mitsui Engineering & Shipbuilding Co., Ltd. Chiba Works F-term (reference) 2G066 AC01 BA08 BA30 BA01 BB01 BB15

Claims (3)

[Claims] In a furnace which raises the temperature by burning combustibles inside, the temperature of the combustion gas in the furnace is controlled through a viewing window provided at an outer end of a nozzle protruding from the furnace body. When measuring with a radiation thermometer installed outside the viewing window, the temperature of the combustion gas measured by the radiation thermometer is characterized in that a low-temperature gas in the vicinity of the viewing window in the nozzle is driven off by an optical inert gas. Measurement method. 2. A method for measuring a combustion gas temperature by a radiation thermometer according to claim 1, wherein argon, nitrogen, oxygen, water vapor, air, or a mixed gas thereof is used as the optical inert gas. . 3. An optical inert gas is introduced into the nozzle at a density of 2.0 × 10 ² mm / s or more and 5.0 × 10 ³ mm / s.
The method for measuring a combustion gas temperature by a radiation thermometer according to claim 1 or 2, wherein the low-temperature gas in the nozzle is driven away by injecting the gas near the viewing window in the nozzle at a flow rate of less than. .