Patent Description:
The boiler mainly converts the chemical energy in the fuel into thermal energy stably and continuously through the process of burning the fuel, and uses this thermal energy to heat water or heat medium as a heat source for drying or heating, or a power source.

However, although the use of boilers brings convenience to factory operations, it is also accompanied by environmental issues. For example, the exhaust gases such as sulfur oxide, SOx, nitrogen oxide, NOx, carbon monoxide, CO, and carbon dioxide, CO2, emitted from the boiler during the combustion of the fuel cause serious environmental pollution, increase the greenhouse effect and lead to global warming. Moreover, the particulate matters, PM2. <NUM>, produced after combustion degrade the air quality and endanger human health. The earliest solution is to dispose a cloth bag to the exhaust outlet to absorb the particles and exhaust gas emitted after combustion as much as possible. However, under the requirements of environmental protection, the emission requirements of nitrogen oxides are becoming more and more stringent, and such method of using cloth bags to absorb exhaust gas can no longer meet the current environmental protection regulations.

Therefore, it is imperative to develop combustion methods that comply with environmental regulations and have lower exhaust emissions. Document <CIT> discloses a prior art combustion method.

Embodiments of the present invention provide a combustion method for controlling and monitoring exhaust emissions in boilers. The inventor found that by gradually introducing combustion improver into the boiler (such as reducing the temperature inside the boiler by <NUM> as a stage interval), the flue gas generated by the combustion of the boiler can be gradually reduced. That is, the NOx concentration is reduced, and the production of carbon monoxide, CO, can be simultaneously avoided by controlling the amount of combustion improver added to the boiler.

The method according to the invention is described in claim <NUM>.

The present invention provides a combustion method for controlling and monitoring exhaust gas emissions in a boiler. The combustion improver is added to the boiler in batches, and the relationship between the data of the amount of combustion improver added, the temperature in the boiler and the exhaust gas emission is monitored. The benefit effects of the invention are that the addition of the combustion improver does gradually reduce the flue gas produced by boiler combustion, and the concentration of NOx emitted can be reduced. Besides, the amount of combustion improver added to the boiler can be controlled to prevent generation of carbon monoxide. That is, when carbon monoxide, CO, is generated in the boiler, the amount of combustion improver introduced into the boiler is reduced to avoid the generation of carbon monoxide, CO.

In order to understand the present invention more clearly, a working principle and process of a combustion method will be introduced below with reference to <FIG>, so as to facilitate the subsequent understanding of the present invention. As illustrated in <FIG>, a flowchart of a combustion method for controlling and monitoring exhaust gas emissions in a boiler according to an embodiment of the invention is shown. As shown in <FIG>, the combustion method of the invention is suitable for combustion in the boiler, the combustion method comprises the following steps.

In a step S10, a liquid fuel is provided in a boiler, and the liquid fuel is burned under atmospheric pressure to make the steam pressure of the boiler reaches <NUM>/cm<NUM>.

In a step S20, a first combustion temperature in the boiler is measured, and an initial concentration of a first exhaust gas in the boiler is monitored.

In a step S30, a combustion improver is added to the boiler in batches, an emission concentration of the first exhaust gas in the boiler is monitored, and the steam pressure of the boiler at <NUM>-<NUM>/cm<NUM> is maintained. The emission concentration is less than the initial concentration.

In a step S40, the step S20 to the step S30 is repeated. The gas emission from the boiler is monitored until a second exhaust gas is generated. The combustion improver is stopped adding. The temperature inside the boiler is measured as a second combustion temperature, and the rate of adding of the combustion improver is reduced to a critical rate to prevent the generation of the second exhaust gas.

In one embodiment of the invention, the liquid fuel of the disclosure is low-sulfur fuel oil, and the combustion improver is water vapor. Preferably, the low-sulfur fuel oil is fuel oil containing vegetable oil such as palm oil.

According to the invention, the boiler is heated with a medium at a steam pressure between <NUM>-<NUM>/cm<NUM> and the exhaust gas emissions from the boiler are measured. In one embodiment, the medium is water.

In one embodiment in the step S10, the liquid fuel is provided at a rate between <NUM>-<NUM> liters/hour. In the step S30, the combustion improver is provided at the critical rate greater than or equal to <NUM>/hour and less than <NUM>/hour. That is, the aforementioned rate is the critical rate, and the rate of adding the combustion improver is controlled within the range of the critical rate to avoid the generation of the second exhaust gas, which will be further described below.

In an embodiment the first combustion temperature ranges from <NUM> to <NUM>, and the second combustion temperature is less than <NUM>.

In one embodiment, the liquid fuel is used for combustion to heat the medium, while the combustion improver is used to reduce the flame temperature inside the boiler, thereby reducing the generation of sulfur oxides, SOx, and nitrogen oxides, NOx, during the combustion process.

Moreover, the step of adding the combustion improver to the boiler in batches in the step S30 further comprises adding the combustion improver in batches at a stage interval of <NUM>, and simultaneously measuring the first combustion temperature and the corresponding concentration of the first exhaust gas. For example, referring to the Table <NUM> below, when the temperature in the boiler is <NUM>, the combustion improver is introduced into the boiler at a rate of <NUM>/hour, and when the temperature in the boiler is <NUM>, the combustion improver is introduced into the boiler at a rate of <NUM>/hour. Briefly, the addition of combustion improver will cause a decrease in the temperature inside the boiler. After adding the combustion improver, the temperature in the boiler decreasing at an interval of <NUM> (due to the addition of combustion improver) as a default value is detected, the amount of the combustion improver added into the boiler is adjusted correspondingly, and the temperature in the boiler and the corresponding flue gas emitted by the boiler (including nitrogen oxides (NOx) and carbon monoxide (CO)) are monitored. This will be explained in detail in Table <NUM> below.

Referring to <FIG> and Table <NUM>, in step S10, after the liquid fuel in the boiler starts to burn, the initial temperature (that is, the first combustion temperature) measured in the boiler is <NUM>. Before the combustion improver is added, the concentration of the first exhaust gas (i.e., nitrogen oxides (NOx)) is measured to be <NUM> P. M (such as step S20). As the combustion proceeds, as in step S30, the combustion improver is added to the boiler in batches, and the combustion improver is added at a critical rate. In this embodiment, the critical rate is <NUM>/hr, and it can be seen that the concentration of the first exhaust gas (i.e., nitrogen oxides (NOx)) decreases to <NUM> P. Then, the combustion improver is added into the boiler in batches and the amount of combustion improver added is increased based on the first combustion temperature decreased into the boiler at an interval of <NUM>. It can be seen that for every <NUM> decreased in the first combustion temperature in the boiler, the corresponding nitrogen oxide, NOx, is also decreased, and at the same time, no sulfur oxide, Sox, or carbon monoxide, CO, is produced in the boiler. For example, referring to the Table <NUM> above, when the temperature inside the boiler is <NUM>, the combustion improver is added into the boiler at a rate of <NUM>/hour, and when the temperature inside the boiler is <NUM>, the combustion improver is added into the boiler at a rate of <NUM>/hour.

In a preferred embodiment, when the rate (critical rate) of adding the combustion improver reaches <NUM>/hour, the first combustion temperature in the boiler is also gradually reduced to <NUM>. The emission of nitrogen oxides, NOx, has decreased from <NUM> P. initially to <NUM> P. , with a reduction of <NUM>%. In this embodiment, the critical rate is to provide the combustion improver at a rate greater than or equal to <NUM>/hour and less than <NUM>/hour. That is, the amount of the combustion improver is controlled to be added to the boiler at an amount greater than or equal to <NUM>/hour but not more than <NUM>/hour.

When the rate of combustion improver added is greater than the critical rate to <NUM>/h, the temperature in the boiler is reduced to <NUM>, and the emission of nitrogen oxides, NOx, is decreased to <NUM> P. However, it is monitored that the combustion process in the boiler produces a second exhaust gas (that is, carbon monoxide), and the concentration of the second exhaust gas is <NUM> P. Correspondingly, the temperature inside the boiler is the second combustion temperature. Once the second exhaust gas is generated, it means that incomplete combustion occurs in the boiler. It is necessary to temporarily stop adding the combustion improver to make the temperature inside the boiler back to a temperature higher than the second combustion temperature.

Therefore, by controlling the rate of adding the combustion improver into the boiler and monitoring the corresponding temperature in the boiler corresponding to different rate of adding the combustion improver into the boiler, this enables the boiler to achieve an ideal combustion state that minimizes the emission of nitrogen oxides, NOx, and does not accompany the generation of carbon monoxide, CO, and sulfur oxides, SOx.

Referring to Tables <NUM>, <NUM>, and <NUM>, in the following examples <NUM>-<NUM>, the combustion method of the disclosure, a <NUM>-ton horizontal smoke tube boiler comprising a low-pressure oil pump and a burner is used to burn the fuel oil of examples <NUM>-<NUM>, The pollutant data in the flue gas that has not been processed by exhaust gas treatment equipment (such as scrubber) is measured through portable detection equipment.

Ingredients in the used fuel composition:.

In this example, the above-mentioned <NUM>-ton horizontal smoke tube boiler is used to implement the combustion method shown in <FIG>, and the above-mentioned special low-sulfur fuel oil is provided as the liquid fuel. The liquid fuel is provided at a rate of <NUM> liters/hour, and the combustion improver is not provided in this example, and the pollutant data in the following Table <NUM> are measured by the aforementioned portable detection equipment.

In this example, the above-mentioned <NUM>-ton horizontal smoke tube boiler is used to implement the combustion method shown in <FIG>, and the above-mentioned special low-sulfur fuel oil is provided as the liquid fuel. The liquid fuel is provided at a rate of <NUM> liters/hour, and the combustion improver is provided at a rate of <NUM>/hour, and the pollutant data in the following Table <NUM> are measured by the aforementioned portable detection equipment.

Based on the data of exhaust emissions from Tables <NUM> to <NUM>, it can be seen that the combustion method of the invention provides a combustion method suitable for reducing exhaust gas emissions. The effect of the method is to reduce the generation of air pollutants such as sulfur oxides, SOx, and nitrogen oxides, NOx, after combustion. The measured data of sulfur oxides, SOx, and nitrogen oxides, NOx, in exhaust emissions are in comply with the latest boiler pollutant emission standards published by the government's environmental protection department. In this way, the problem of excessive air pollutants and fine suspended particulate matters encountered in the conventional boiler operation method can be solved, and the pollutants such as sulfur oxides, SOx, and nitrogen oxides, NOx, in the exhaust gas after combustion can be reduced.

In addition, the combustion method provided by the invention is suitable for use in conventional boilers, it is unnecessary to construct new equipment or transform conventional boilers. It avoids the additional safety problems such as careless use, natural gas leakage, etc. that may be encountered in the construction of new pipelines or storage tanks when the boiler system is changed to a new fuel with low flammable and explosive flash point, such as natural gas. The invention provides a safe, convenient, and economical combustion method for factories to reduce exhaust emissions by installing new boilers or using conventional boilers.

Claim 1:
A combustion method for controlling and monitoring exhaust gas emissions in boilers, comprising steps of:
a step S10 of providing a liquid fuel in a boiler, burning the liquid fuel under atmospheric pressure to make the steam pressure of the boiler reach <NUM>/cm<NUM>;
a step S20 of measuring a first combustion temperature in the boiler, and monitoring an initial concentration of a first exhaust gas in the boiler;
a step S30 of adding a combustion improver to the boiler in batches, and monitoring an emission concentration of the first exhaust gas in the boiler, maintaining the steam pressure of the boiler at <NUM>-<NUM>/cm<NUM>, and wherein the emission concentration is less than the initial concentration, wherein by gradually introducing the combustion improver into the boiler, the first exhaust gas generated by the combustion of the boiler is gradually reduced; and
a step S40 of repeating the steps S20 to S30, and monitoring the boiler until a second exhaust gas is generated, and measuring the temperature inside the boiler as a second combustion temperature,
once the second exhaust gas is generated, temporarily stopping adding the combustion improver until the temperature inside the boiler is back to be higher than the second combustion temperature, and reducing a rate of adding of the combustion improver to a rate not greater than a critical rate so as to prevent the generation of the second exhaust gas; after stopping adding the combustion improver, repeating the steps S20 to S30 to maintain the temperature inside the boiler between the first combustion temperature and the second combustion temperature; and
wherein the combustion improver is water vapor.