RU119860U1 - BOILER - Google Patents

Abstract

A heating boiler containing an insulated casing with a combustion chamber with gas burners located in its lower part, above which a heat exchanger is located in the form of a set of metal pipes with baffle plates and an inlet and outlet for water, as well as a flue gas collector, characterized in that it is additionally equipped with thermoelectric converters in the form of a battery of thermocouples located in the combustion chamber between the gas burners and the heat exchanger, the output of which through the voltage inverter is connected to the electric motor of the injection pump and the ozonizer connected by means of an air duct through the injection pump to the combustion chamber.

Description

A heating boiler belongs to the power system, in particular, to heat generators, and can be used for autonomous heating and hot water supply of individual houses, industrial buildings and structures.

A heating boiler is known that contains an insulated casing with a combustion chamber with gas burners located in its lower part, above which there is a heat exchanger in the form of a set of metal pipes with reflective plates and water inlet and outlet, as well as a flue gas collector (see patent WO 93 / 05347, 03/18/1993).

The disadvantage of this boiler is the relatively high fuel consumption per unit of heat produced, as well as the increased content of carbon monoxide and nitrogen oxides (NO and NO ₂ ) in the composition of the combustion products.

The technical result of the proposed utility model is to increase the efficiency of the heating boiler and reduce the harmful effects of combustion products.

This technical result is achieved in that a heating boiler containing an insulated casing with a combustion chamber with gas burners located in its lower part, above which there is a heat exchanger in the form of a set of metal pipes with reflective plates and an inlet and outlet for water, as well as a flue gas collector, characterized in that it is additionally equipped with thermoelectric converters in the form of a battery of thermocouples located in the combustion chamber between gas burners and a heat exchanger, the output of which ithout voltage inverter connected to the motor of the booster pump and ozonator connected by duct through a pressure pump with a combustion chamber.

Figure 1 presents a section of a heating boiler.

The heating boiler contains an insulated casing 1, including a combustion chamber 2 located in the lower part with gas burners 3, above which there is a heat exchanger 4 made of a combination of pipes made of copper or a copper-nickel alloy with reflective plates 5 and connected to the input 6 and output 7 for water, as well as a flue gas collector 8 with an outlet 9. In the combustion chamber 2 between the gas burners 3 and the heat exchanger 4 there are thermoelectric converters 10 in the form of a thermocouple battery. The output of the thermoelectric converters 10 through the voltage inverter 11 is connected to the electric motor 12 of the injection pump 13 and the ozonator 14. The ozonizer 14 is connected via the air pump 15 to the combustion chamber 2 through the injection pump 13.

The heating boiler operates as follows. The coolant from the system is fed into the insulated body of the boiler 1 through the inlet 6, then passes through the set of pipes of the heat exchanger 4, heats up and exits through the outlet 7 to the consumer. The heat exchanger 4 is selected low-capacity (with pipes made of copper or copper-nickel alloy with an inner diameter equal to 21-23 mm), and with external fins, which allows you to effectively remove heat from heat-containing flue gases passing from gas burners 3 in the combustion chamber 2 through the heat exchanger 4 into the collector 8. The pipes of the heat exchanger 4 are coated on top with reflective plates 5, creating a swirl of the flue gas stream, thereby increasing the efficiency of their heat use. Flue gases, having given heat through the heat exchanger 4 to the heat carrier, enter the collector 8, from where they are led out through the outlet 9.

Thermoelectric converters 10, being influenced by different-temperature media in the combustion chamber 2, convert part of the thermal energy of the heating boiler into electrical energy. In accordance with the Seebeck phenomenon, a constant electric voltage (thermoEMF) appears at the output of the thermoelectric converters 10, which is supplied to the voltage inverter 11, where it is converted to alternating electric voltage. Further, this voltage is supplied to the electric motor 12 of the injection pump 13 and to the ozonator 14. In the ozonizer 14, air ozonation occurs due to a barrier discharge. As a result, an ozone-air mixture is formed, which is pumped by a blower 13, which is driven by an electric motor 12, into the combustion chamber 2. In the combustion chamber 2, an ozone-produced mixture with enhanced oxidizing properties is involved in gas combustion, intensifies the combustion process and improves the composition flue gas. Thus, there is fuel economy and improvement of the environmental performance of the boiler.

The theoretical justification for the positive effect of the ozone-air mixture on the gas combustion process is presented below.

Natural gas entering most modern boiler houses, in the volume of one cubic meter, has the following composition:

1. CH ₄ (methane) - 941.2 L

2. H ₂ (hydrogen) - 4.4 L

3. N ₂ (nitrogen) - 24.6 l

4. C ₂ H ₄ (ethane) - 24.1 L

5. C ₃ H ₈ (propane) - 4.3 L

6. With ₄ H ₁₀ (butane) - 0.5 L

7. With ₅ H ₁₂ (pentane) - 0.6 L

8. C ₆ H ₁₄ (hexane) - 0.3 L

With the complete combustion of natural gas, the following chemical reactions will occur:

1. CH ₄ (r) + O ₂ = CO ₂ (r) + 2H ₂ O

ΔcrH ⁰ = -802.25 kJ / mol

2.2H ₂ (r) + O ₂ (r) = 2H ₂ O

ΔcrH ⁰ = -241.812 kJ / mol

3. N ₂ (r) + 2O ₂ (r) = 2NO ₂ (r)

ΔcrH ⁰ = 66 kJ / mol

4. 2С ₂ H ₆ (r) = 7O ₂ (r) = 4С0 ₂ (r) + 6Н ₂ O (r)

ΔcrН ⁰ = -1427? 8 kJ / mol

5 C ₂ H ₅ (r) + 5O ₂ (r) = 3CO ₂ (r) + 4H ₂ O (r)

ΔcrH ⁰ = -2043.13 kJ / mol

6. With ₅ P ₁₂ (r) + 13O ₂ (r) = 8CO ₂ (r) + 10H ₂ O (r)

ΔcrH ⁰ = -2658.4 kJ / mol

7.C ₂ H ₁₂ (r) + 8O ₂ (r) = 5CO ₂ (r) + 6H ₂ 0 (r)

ΔcrH ⁰ = -3271.9 kJ / mol

8.2C ₆ H ₁₄ (r) + 19O ₂ (r) = 12CO ₂ (r) + 14H ₂ O (r)

ΔcrH ⁰ = -3883.7 kJ / kg,

where ΔcrH ⁰ is the combustion enthalpy.

Theoretical calculation of the amount of heat released during the complete combustion of 1 cubic meter. meters of natural gas, gives a value of 35811.154 kJ. As can be seen from the presented reaction equations during combustion, water vapors are formed that react with methane and other gases, especially at temperatures above 600 ° K. Since methane CH ₄ is the main component in natural gas, the following reactions become possible:

1. CH ₄ (r) + 2H ₂ O (r) = CO ₂ (r) = 4H ₂ (r)

ΔcrH ⁰ ₁ = + 165.6 kJ / mol

2. CH ₄ (r) + H ₂ O (r) = CO (r) + 3H ₂ (r)

ΔcrH ⁰ ₁ = + 206.15 kJ / mol

3. CH ₄ (r) + CO ₂ (r) = 2CO (r) + 2H ₂ (r)

ΔcrH ⁰ ₁ = + 247.35 kJ / mol

4.2CH ₄ (r) + 3O ₂ (r) = CO (r) + 2H ₂ O (r)

ΔcrH ⁰ ₁ = -520 kJ / mol

The first three modes, as you can see, go with the absorption of heat (endothermic), the fourth equation represents the process of incomplete combustion of methane to carbon monoxide, which leads to a loss of 282 kJ / mol of heat. So, incomplete combustion leads to a sharp drop in the heat transfer of the reaction to 35%. In addition, carbon monoxide is a particularly hazardous polluting substance.

Based on the foregoing, it becomes obvious that there is a significant reserve for intensifying the combustion process and creating conditions for more complete combustion of natural gas.

According to the Arrhenius equation, the rate constant of chemical transformations is determined by the temperature T and the activation energy of molecules E ₀ :

K ₁ = K ₀ exp (-E ₀ / RT),

where K ₁ is the rate constant of chemical transformations;

K ₀ - coefficient reflecting the number of all collisions of reacting molecules per unit time;

exp (-E ₀ / RT) is the fraction of the total number of molecules capable of reaction.

Thus, in order to increase the rate constant of a chemical reaction in a medium, it is necessary to increase the temperature or lower the activation energy of molecules. The increase in temperature is associated with significant technical difficulties, so the second way remains more acceptable. It is known that the reaction rate is mainly determined by the energy stored on the vibrational degree of freedom of the molecule. In this regard, it is necessary to ensure the conditions for chemical reactions under which the bulk of the energy input is spent on vibrational excitation of molecules. In this case, a non-equilibrium molecular gas is formed, which contributes to the activation of chemical transformations of substances in the air.

The simplest way is to lower the activation energy of molecules and to obtain a nonequilibrium molecular gas in an air medium by creating a high-voltage sharply inhomogeneous electric field in it. In addition, gas ions and free electrons upon collisions with fuel molecules change the internal structure of the latter. As a result of these changes, the fuel molecule goes into an excited state, and the activation energy of E molecules decreases.

One of the typical reactions in discharge plasma is the reaction of ozone formation. The main role in the formation of ozone is played by electronically excited oxygen molecules resulting from the collision of molecules with electrons. Under the influence of electron energy, an oxygen molecule goes into an excited state, characterized by increased reactivity, which leads to ozone formation reactions. Ozone eliminates the induction period characteristic of the oxidation of saturated hydrocarbons by oxygen, and the oxidation of hydrocarbons is accelerated by very small amounts of ozone.

Thermally, ozone begins to decompose noticeably at 100 ° C; therefore, at room temperature, the oxidation of hydrocarbons occurs predominantly by reaction with ozone:

RH + O ₃ ⇒RO + H ₂ O

The thermal effect for methane is 11.5 kcal / mol. At a temperature exceeding 100 ° C, atomic kolor formed during the decomposition of ozone into O ₂ and O begins to play a noticeable role. The effect of ozone on the kinetics of hydrocarbon oxidation is mainly due to its role in initiating a chain reaction. The effective activation energy of hydrocarbon oxidation in the presence of ozone is significantly reduced, which changes the ignition conditions quite strongly, shifting the lower ignition limit to lower temperatures and pressures. In addition, ozone accelerates the spread of flame in mixtures of hydrocarbons with air as a result of acceleration of oxidative reactions.

Thus, through the use of an ozone-air mixture during the burning of fossil fuels, this process can be significantly intensified and a more complete use of natural gas in heating boilers can be achieved. Ultimately, this is reflected in a reduction in gas consumption by 15 ... 20% and a reduction in harmful emissions into the atmosphere.

Consider the efficiency of the claimed utility model, implemented on the basis of a serial heating boiler with a thermal power of 11.6 kW. This boiler in normal operation consumes 1.18 cubic meters of natural gas per hour (or 28.32 cubic meters per day). For the normal operation of the combustion chamber 2 of this boiler during the day, 283.2 cubic meters will be required. m of drained air.

Considering that the air usually contains 21% oxygen (one fifth), it can be concluded that 59.47 cubic meters will be required for burning the indicated amount of natural gas. m of oxygen. When replacing oxygen with ozone, the latter will require much less, since the oxidizing properties of ozone significantly exceed the oxidizing properties of oxygen. It has been established that, taking into account technological requirements, a positive result of the influence of the ozone-air mixture on the combustion of natural gas is achieved with the addition of 400 mg of ozone per 1 m ^{3 of} gas. In terms of the conditions of our example, for the operation of the boiler during the day, 0.011 kg of ozone will be needed.

Upon receipt of ozone on modern electrozonators, the energy consumption is 14 ... 18 kWh per kilogram of ozone. Thus, in our example, the operation of the ozonizer 14 during the day will require 0.2 kWh of electrical energy.

To pump the required amount of ozone-air mixture into the combustion chamber 2 using a pump 13, an electric motor 12 with a power of 60 ... 80 W is required. During the day for the operation of the electric motor 12, 1.92 kWh of electrical energy will be consumed.

Total, to receive and supply the ozone-air mixture into the combustion chamber 2 of the boiler during the day, electric energy is required in the amount of Q _{el '} = 0.2 + 1.92 = 2.12 kW h. This energy is converted by thermoelectric converters 10 due to the part thermal energy generated by the boiler.

Thermal energy converted into electrical energy and directed to the operation of the ozonizer 14 and the electric motor 12 of the blower fan 13 during the day can be determined in accordance with the expression:

,

where η _ozone - efficiency thermoelectric converters 10, η _ozone = 0.1.

η _stat - efficiency static converter 11, η _stat = 0.97.

After substituting the numerical values, we obtain: Q _heat = 21.9 kW h.

As a result of the claimed utility model, the consumption of natural gas is reduced by 15 ... 20%, which during the day will amount to 4.5 cubic meters. The saved amount of natural gas during its combustion will allow to obtain a thermal power of 1.84 kW or thermal energy in the amount of 44.16 kWh per day, which is twice the amount of thermal energy taken from the boiler to ensure the operability of the ozonizer 14 and electric motor 12 of the injection pump 13 In addition, the use of the claimed utility model can reduce the environmental damage of combustion products by reducing the content of carbon monoxide and nitrogen oxides.

Claims (1)

A heating boiler comprising an insulated casing with a combustion chamber with gas burners located in its lower part, above which there is a heat exchanger in the form of a set of metal pipes with reflective plates and water inlet and outlet, as well as a flue gas collector, characterized in that it is additionally equipped with thermoelectric converters in the form of a thermocouple battery located in the combustion chamber between gas burners and a heat exchanger, the output of which is connected to a motor through a voltage inverter m booster pump and ozonator connected by duct through a pressure pump with a combustion chamber.