CN103953925B - Energy-saving and environment-friendly device of photon energy boiler - Google Patents

Abstract

The invention provides an energy-saving and environment-friendly device of a photon energy boiler, which comprises a fuel and gas pretreatment device, a premixing device and a combustion chamber, wherein the fuel and gas pretreatment device comprises a shell, ceramic chips and springs, one end of the shell is provided with a fuel and gas inlet, the other end of the shell is a fuel and gas outlet, the ceramic chips are arranged in the shell, and the springs are arranged among the ceramic chips; the premixing device comprises a premixing chamber and a turbofan, wherein one end of the premixing chamber is provided with a fuel and gas injection port, the other end of the premixing chamber is provided with an air outlet, an air inlet is formed in the upper side, close to the fuel and gas injection port, of the premixing chamber, and the turbofan is arranged in the middle of the premixing chamber. The invention has good atomization effect, fuel oil and gas are uniformly mixed with air, and the heat transfer and thermal collision speed and the combustion efficiency are improved through the photon energy field.

Description

A photon energy boiler energy saving and environmental protection device

technical field

The invention belongs to the field of industrial energy saving and emission reduction, and in particular relates to an energy saving and environmental protection device for a photon energy boiler.

Background technique

my country's industrial boilers have a large quantity and a wide range. By the end of 2008, there were 570,000 industrial boilers in use in my country. Due to the large amount of soot and pollutants such as sulfur dioxide and nitrogen oxides emitted by industrial boilers, it has become one of the main sources of air pollution in my country. The annual pollutant discharge of industrial boilers in my country is about: smoke and dust: 8 million t/a; CO2: 1.25 billion t/a. At present, on the whole, the energy consumption and pollution discharge of industrial boilers rank second in the national industrial industry, second only to power plant boilers, and the energy consumption is much higher than that of high energy-consuming industries such as steel and petrochemical industries. The combustion rate of existing boilers Low thermal efficiency and serious exhaust pollution.

Contents of the invention

The object of the present invention is to solve the above-mentioned defects in the prior art, and provide an energy-saving and emission-reducing device for a photon energy boiler that can increase the combustion rate, save energy and reduce emissions.

The solution adopted by the present invention is: an energy-saving and environmental protection device for a photon energy boiler, which is characterized in that it includes a fuel gas pretreatment device, a premixing device and a combustion chamber, and the fuel gas pretreatment device includes a shell, a ceramic chip and a spring, One end of the casing is provided with a fuel gas inlet, the other end of the casing is a fuel gas outlet, the ceramic chips are arranged inside the casing, and the springs are arranged between the ceramic chips; the premixing device includes a premixing device A mixing chamber and a turbofan, one end of the premixing chamber is provided with a fuel gas injection port, the other end of the premixing chamber is provided with an air outlet, and the upper side of the premixing chamber near the fuel gas injection port is provided with an air inlet, the The turbofan is arranged in the middle of the premixing chamber, the fuel gas outlet of the fuel gas pretreatment device is connected to the fuel gas injection port of the premixing device, and the gas outlet of the premixing device is connected to the combustion chamber Connected, the inner wall of the combustion chamber is sprayed with photon energy spraying material, the composition and weight percentage of the photon energy spraying material are: zirconium cerium oxide solid solution: 5%-20%, cobalt oxide: 1%-6%, iron oxide: 4%-10%, titanium oxide: 2%-7%, lanthanum oxide: 2%-8%, yttrium oxide: 1%-4%, silicon carbide: 30%-80%.

Further, the shell is made of stainless steel, and the spring is made of corrosion-resistant stainless steel.

Further, the ceramic chip has a honeycomb structure, and air holes are provided on the ceramic chip.

Furthermore, the composition and ratio of the ceramic chip are: zirconium cerium oxide solid solution: 2%-8%, manganese oxide: 1%-8%, cobalt oxide: 2%-5%, titanium oxide: 3% %-6%, chromium oxide: 5%-8%, lanthanum oxide: 1%-9%, iron oxide: 2%-7%, yttrium oxide: 1%-3%, molybdenum sulfide: 2%-5%, Silicon carbide: 25%-60%, tourmaline: 8%-30%, binder: 3%-5%.

Further, the angle of the fuel gas injection port is 45°-90°.

Further, the inclination angle of the turbofan blades is 15°-45°, and the number of turbofan blades is 5-25.

Further, the inner surface of the premixing device is provided with ionized material.

The advantages of the present invention are: the present invention activates fuel gas molecules through the fuel gas pretreatment device, promotes fission, and achieves the purpose of atomization. The end of the premixing device that is provided with fuel gas inlet and air inlet first mixes fuel gas with air , through the turbofan to make the mixed gas into a rotating form for secondary mixing, so that the fuel gas and air can be mixed more fully. By spraying photon energy spraying materials on the inner wall of the combustion chamber, a photon energy field is formed to increase heat transfer and thermal spray speed, and improve combustion efficiency.

Description of drawings

Fig. 1 is the structure of a kind of photon energy boiler energy-saving and environmental protection device proposed by the present invention;

Fig. 2 is an enlarged view of the structure of the fuel gas pretreatment device described in Fig. 1;

Fig. 3 is an enlarged view of the structure of the premixing device described in Fig. 1;

Fig. 4 is a side view of the ceramic chip of the present invention;

Fig. 5 is a top view of the ceramic chip according to the present invention.

detailed description

The present invention is described below in combination with specific embodiments.

Embodiment one

Referring to Fig. 1 to Fig. 5, Fig. 1 is the structure of a photon energy boiler energy-saving and environmental protection device proposed by the present invention; Fig. 2 is an enlarged view of the structure of the fuel gas pretreatment device described in Fig. 1; An enlarged view of the structure of the premixing device described above.

As shown in Figure 1, Figure 2 and Figure 3, a photon energy boiler energy-saving and environmental protection device is characterized in that it includes a fuel gas pretreatment device 1, a premixing device 2 and a combustion chamber 3, and the fuel gas pretreatment device 1 It includes a casing 11, a ceramic chip 12 and a spring 13. One end of the casing 11 is provided with a fuel gas inlet 14, and the other end of the casing 11 is a fuel gas outlet 15. The ceramic chip 12 is arranged inside the casing 11. The spring 13 is arranged between the ceramic chips 12; the premixing device 2 includes a premixing chamber 21 and a turbofan 22, one end of the premixing chamber 21 is provided with a fuel gas injection port 23, and the premixing chamber 21 The other end is provided with an air outlet 25, and the premix chamber 21 is provided with an air inlet 24 near the upper side of the fuel gas injection port 23, and the turbofan 22 is arranged in the middle of the premix chamber 21, and the fuel gas pretreatment The fuel gas outlet 15 of the device 1 is connected to the fuel gas injection port 23 of the premixing device 2 , and the gas outlet 25 of the premixing device 2 is connected to the combustion chamber 3 .

In the embodiment of the present invention, the fuel and gas pretreatment device is a device for pretreating fuel or gas. The fuel or gas enters the pretreatment device, and the fuel and gas are pretreated by the photon energy high-energy ceramic chip arranged inside the casing. The fuel gas enters the premixing device to be mixed with air and output to the combustion chamber for combustion.

In the embodiment of the present invention, several photon-energy high-energy ceramic chips are arranged in the preprocessing device, and corrosion-resistant springs are arranged between the photon-energy high-energy ceramic chips.

In the embodiment of the present invention, fuel gas molecules are activated through the fuel gas pretreatment device to promote fission, which is beneficial to achieve the purpose of atomization.

The inner wall of the combustion chamber 3 is sprayed with photon energy spray material.

In the embodiment of the present invention, the photon energy spraying material is sprayed on the inner wall of the combustion chamber to form a photon energy field, which improves heat transfer and thermal spray speed, and improves combustion efficiency.

The invention provides a photon energy spraying material for spraying in a combustion chamber, which is made of the following raw materials in weight percentage: 5%-20% of zirconium cerium oxide solid solution, 1%-6% of cobalt oxide, and 4%-10% of iron oxide %, titanium oxide 2%-7%, lanthanum oxide 2%-8%, yttrium oxide 1%-4%, silicon carbide 30%-80%.

The shell 11 is made of stainless steel, and the spring 13 is made of corrosion-resistant stainless steel. In the embodiment of the present invention, the stainless steel casing is a cylinder or other irregular shapes.

The ceramic chip 12 has a honeycomb structure, and air holes 16 are provided on the ceramic chip 12 .

In the embodiment of the present invention, the photon-energy high-energy ceramic chip is in the shape of a honeycomb, with a number of vent holes 12 for gas to pass through. Referring to Fig. 4 and Fig. 5, Fig. 4 is a side view of the ceramic chip according to the present invention; Fig. 5 is a top view of the ceramic chip according to the present invention.

The angle of the fuel gas injection port 23 is 45°-90°.

In the embodiment of the present invention, the fuel gas inlet is set at 45° to 90°, so that the fuel gas collides with the pipe wall when it is sprayed out, and further breaks up the fuel gas molecular clusters, so as to facilitate a better connection with the air at the air inlet. mix.

The inclination angle of the turbofan 22 blades is 15°-45°, and the turbofan blades are 5-25 pieces.

In the embodiment of the present invention, the end of the premixing device provided with the fuel gas inlet and the air inlet first mixes the fuel gas with air, and the mixed gas is rotated by a turbofan for secondary mixing, and the high-energy ionization of the inner wall of the premixing device The material promotes the ionization of fuel gas, so that the fuel gas and air are more fully mixed, and the mixed gas is finally injected into the combustion chamber through the outlet hole and connected to the burner for combustion.

The invention provides a ceramic chip used in a fuel gas pretreatment device, the composition and ratio of which are: 2%-8% of zirconium cerium oxide solid solution, 1%-8% of manganese oxide, 2%-8% of cobalt oxide 5%, titanium oxide 3%-6%, chromium oxide 5%-8%, lanthanum oxide 1%-9%, iron oxide 2%-7%, yttrium oxide 1%-3%, molybdenum sulfide 2%-5 %/, silicon carbide 25%-60%, tourmaline 8%-30%, binder 3%-5%.

In the embodiment of the present invention, the silicon carbide in the components of the ceramic chip can be replaced by silicon oxide, silicon nitride or silicon acetate.

The ceramic chip provided by the invention is synthesized with lanthanide elements and transition metal elements and used in cooperation with far-infrared materials in energy-saving and environmental protection devices for photon energy boilers.

Embodiment two

An embodiment of a ceramic chip provided by the present invention is: the composition and proportion of the ceramic chip are: 15% of zirconium cerium oxide solid solution, 4% of manganese oxide, 3% of cobalt oxide, 4% of titanium oxide, 6% of chromium oxide %, lanthanum oxide 4%, iron oxide 2%, yttrium oxide 3%, molybdenum sulfide 5%, silicon carbide (or silicon oxide or silicon nitride or silicon acetate) 25%, tourmaline 25%, binder 4%.

The above materials (except lanthanide rare earth elements and zirconium cerium oxide solid solution) were ball milled to 1000 mesh and then mixed, and calcined at 750 degrees for 10 hours and then ball milled to 2000 mesh again. It is prepared by the method, and then it is stamped and formed by adding a binder, and then calcined at 1232 degrees.

Embodiment three

The second embodiment of a ceramic chip provided by the present invention is: the composition and ratio of the ceramic chip are: 12% of zirconium cerium oxide solid solution, 5% of manganese oxide, 3% of cobalt oxide, 5% of titanium oxide, Chromium 6%, lanthanum oxide 5%, iron oxide 5%, yttrium oxide 2%, molybdenum sulfide 7%, silicon carbide (or silicon oxide or silicon nitride or silicon acetate) 20%, tourmaline 30%, binder 5 %.

The above materials (except lanthanide rare earth elements and zirconium cerium oxide solid solution) were ball milled to 480 mesh and mixed, and calcined at 900 degrees for 8.5 hours, and then ball milled to 1800 mesh again. It is prepared by the method, and then it is stamped and formed by adding a binder, and then calcined at 1180 degrees.

Embodiment four

Another embodiment of a ceramic chip provided by the present invention is: the composition and ratio of the ceramic chip are: 8% manganese oxide, 3% cobalt oxide, 4.5% titanium oxide, 5% chromium oxide, 3% lanthanum oxide, Iron oxide 2%, yttrium oxide 2%, zirconia 2.5%, silicon carbide (or silicon oxide or silicon nitride or silicon acetate) 44%, tourmaline 23%, binder 3%.

The above materials (except lanthanide rare earth elements and zirconium cerium oxide solid solution) were ball milled to 500 mesh and then mixed, and calcined at 850 degrees for 12 hours and then ball milled to 800 mesh again. The lanthanide rare earth element and zirconium cerium oxide solid solution was soaked It is prepared by the method, and then the adhesive is added to stamp it, and then it is calcined at 1280 degrees.

In the embodiment of the present invention, the silicon carbide in the components of the ceramic chip can be replaced by silicon oxide, silicon nitride or silicon acetate.

Embodiment five

An embodiment of a photon energy spraying material provided by the present invention is: 3% cobalt oxide, 6% iron oxide, 5% titanium oxide, 8% zirconium oxide, 6% lanthanum oxide, 3% cerium oxide, 2% yttrium oxide %, silicon carbide (or silicon oxide or silicon nitride or silicon acetate) 67%.

The above materials are ball-milled to 600 mesh and mixed, and calcined at 1300 degrees for 38 hours, and then re-ball-milled to 2000 mesh powder material, which can be sprayed.

Embodiment six

The second embodiment of a photon energy spraying material provided by the present invention is: cobalt oxide 4%, iron oxide 5%, titanium oxide 5%, zirconium oxide 10%, lanthanum oxide 7%, cerium oxide 3%, yttrium oxide 2%, silicon carbide (or silicon oxide or silicon nitride or silicon acetate) 64%.

The above materials are ball-milled to 600 mesh and then mixed, and calcined at 1320 degrees for 35 hours, then re-ball-milled to 2000 mesh powder material, which can be sprayed.

Embodiment seven

Another embodiment of a photon energy spraying material provided by the present invention is: 3.5% cobalt oxide, 5.5% iron oxide, 5% titanium oxide, 15% zirconium oxide, 5% lanthanum oxide, 3% cerium oxide, yttrium oxide 2%, silicon carbide (or silicon oxide or silicon nitride or silicon acetate) 61%.

The above materials are ball-milled to 800 mesh, mixed, and calcined at 1280 degrees for 40 hours, and then re-ball-milled to 2000 mesh powder material, which can be sprayed.

The invention can be used for energy-saving and emission-reduction transformation of existing boilers, and can also be applied to the manufacture of new environment-friendly and energy-saving boilers. The photon energy spraying material of the present invention can also be applied to the inner wall treatment of coal-fired boilers and other industrial furnaces, so the application of the photon energy spraying material of the present invention in combustion is within the protection scope of the present invention.

The energy-saving and environmental protection device of a photon energy boiler provided by the present invention has been introduced in detail above. In this paper, specific examples are used to illustrate the principle and implementation of the present invention. The description of the above embodiments is only used to help understand the present invention. method and its core idea; at the same time, for those of ordinary skill in the art, according to the idea of the present invention, there will be changes in the specific implementation and application scope. Invention Limitations.

Claims (7)

1. A photon energy boiler energy-saving and environmental protection device, characterized in that it comprises: a fuel gas pretreatment device (1), a premixing device (2) and a combustion chamber (3), and the fuel gas pretreatment device (1) includes Housing (11), ceramic chips (12) and springs (13), one end of the housing (11) is provided with a fuel gas inlet (14), and the other end of the housing (11) is a fuel gas outlet (15). The ceramic chips (12) are arranged inside the housing (11), and the springs (13) are arranged between the ceramic chips (12); the premixing device (2) includes a premixing chamber (21) and a vortex fan (22), one end of the premix chamber (21) is provided with a fuel gas injection port (23), and the other end of the premix chamber (21) is provided with an air outlet (25), and the premix chamber (21) An air inlet (24) is arranged near the upper side of the fuel gas injection port (23), the turbofan (22) is arranged in the middle part of the premixing chamber (21), and the fuel gas pretreatment device (1) The fuel gas outlet (15) is connected with the fuel gas injection port (23) of the premixing device (2), and the gas outlet (25) of the premixing device (2) is connected with the combustion chamber (3). The photon energy spraying material is sprayed on the inner wall of the combustion chamber (3), and the components and weight percentages of the photon energy spraying material are: zirconium cerium oxide solid solution, 5%-20%; cobalt oxide, 1%-6%; iron oxide, 4%-10%; titanium oxide, 2%-7%; lanthanum oxide, 2%-8%; yttrium oxide, 1%-4%; silicon carbide, 30%-80%. 2. The energy-saving and environment-friendly device for a photon energy boiler according to claim 1, characterized in that, the housing (11) is made of stainless steel, and the spring (13) is made of corrosion-resistant stainless steel. 3. An energy-saving and environment-friendly device for a photon energy boiler according to claim 1, characterized in that, the ceramic chip (12) has a honeycomb structure, and air holes (16) are arranged on the ceramic chip (12). 4. The energy-saving and environmental protection device for a photon energy boiler according to claim 3, characterized in that, the components and proportioning of the ceramic chip (12) are: zirconium cerium oxide solid solution, 2%-8%; Manganese, 1%-8%; Cobalt oxide, 2%-5%; Titanium oxide, 3%-6%; Chromium oxide, 5%-8%; Lanthanum oxide, 1%-9%; Iron oxide, 2%- 7%; Yttrium oxide, 1%-3%; Molybdenum sulfide, 2%-5%; Silicon carbide, 25%-60%; Tourmaline, 8%-30%; Binder, 3%-5%. 5. The photon energy boiler energy-saving and environmental protection device according to claim 1, characterized in that, the angle of the fuel gas injection port (23) is 45°-90°. 6. The energy-saving and environment-friendly device for a photon energy boiler according to claim 1, characterized in that, the inclination angle of the blades of the turbofan (22) is 15°-45°, and the number of blades of the turbofan is 5-25. 7. The energy-saving and environment-friendly device for a photon energy boiler according to claim 1, characterized in that ionized materials are arranged on the inner surface of the pre-mixing device (2).