RU2634987C1 - Gas-fired burner - Google Patents

Abstract

FIELD: electricity-producing industry.

SUBSTANCE: gas-fired burner comprises a main body frame, a row of the compartmentalized fire grass that are situated in line on the top part of the main body frame. At the upper end surface of each of the fire grass row, there is a row of the firing matrices, wherein the row of the firing matrices is leveled along the length of the fire grass at least in one line; the firing matrix comprises two first tops and at a minimum one second top. Either of the two first tops is capable of the side flame formation along the edge of the top, the second top is capable of the lengthwise flame formation in the top upper direction. The two first tops are placed opposite one another, the extension direction of either of the two first tops corresponds to the extension direction of the fire grass, and the second top is situated between two first tops; the air inlet adjuster is provided on the bottom part of the main body frame.

EFFECT: emissions release reduction.

7 cl, 5 dwg

Description

Technical field

The present invention relates to the field of gas combustion technology and more particularly to a gas burner.

BACKGROUND OF THE INVENTION

Currently, traditional gas burners for the water heater on the market are usually equipped with an atmospheric grate with a number of nozzles located on the tape, in which the gas can be mixed with atmospheric air for combustion in order to increase the burning rate. In such a gas burner, the combustion opening for discharging gas to produce a flame is relatively large. In this configuration, although a greater amount of gas can be released from the furnace opening, the flame temperature is relatively low, since gas or a mixture of gas and air is quickly released and their combustion process is hindered to the full extent, since there is a pronounced limitation in the design calculation. For this reason, 10-20 grate grates may be provided in one conventional gas burner. This is not only a waste of energy, but also increases the cost of a gas burner. In addition, the inefficient combustion of gas causes the appearance of many harmful gases that adversely affect human health.

SUMMARY OF THE INVENTION

Based on this, the aim of the present invention is to provide a gas burner with higher combustion efficiency to overcome the above disadvantages of the prior art.

This document presents a gas burner containing a frame of the main body, a series of grates, separated from each other and arranged in a row on the upper part of the frame of the main body, and on the upper end surface of each of the row of grates there is a series of ignition matrices, while ignition matrices aligned along the length of the grate at least in one line; wherein the ignition matrix contains two first nozzles and at least one second nozzle, each of the first two nozzles is configured to form a side flame along its edge, the second nozzle is configured to form a longitudinal flame in its upper direction, the first two nozzles are located opposite each other friend, the length direction of each of the first two nozzles corresponds to the length direction of the grate, and the second nozzle is located between the two first nozzles; also on the bottom of the frame of the main body is a device for adjusting the air intake.

In one embodiment, the first nozzle is a rectangular nozzle or a trapezoidal nozzle, wherein the first nozzle is equipped with a gas horn on each of the four sides of the first nozzle, and the second nozzle is a cylindrical nozzle with a gas horn on top of the second nozzle.

In one embodiment, both the first nozzle and the second nozzle extend 0.5-1 mm above the upper end surface of the grate.

In one embodiment, the second nozzle is further located in the region between two adjacent ignition matrices on the upper end surface of the grate.

In one embodiment, the frame of the main body is equipped with at least two supporting frames and a row of grate grids mounted on at least two supporting frames side by side and separated from each other.

In one embodiment, each of the at least two support frames is equipped with a series of gas tubes having an exact correspondence with a number of grates.

In one embodiment, the lower part of the main body frame is equipped with a gas inlet adapted to be connected to the gas supply device, the main body frame is further equipped with a tapered conical tube, a pipe with a hidden discharge neck, a diffusion tube, a U-shaped outlet pipe and a distribution pipe connected in series between the gas inlet and the grate, and the distribution pipe is equipped with a number of outlet openings for for having an exact match with a number of grates.

The advantages and main ideas of the above technical solution are explained below.

In the above gas burner, the gas discharged from the first and second nozzles can be ignited to form a blazing flame. The first nozzle is configured to form a side flame along its edge by discharging gas in the lateral direction, and the second nozzle is configured to form a longitudinal flame in the upper direction by discharging gas upward. Longitudinal flame acts as the main source of heat for its good stability and high temperature. In a configuration in which the two first nozzles are located opposite each other and the second nozzle is located between the two first nozzles, the flame formed by the ignition matrix has a W-shape similar to the shape of a sunflower. This configuration has the following advantages. Firstly, the side flame formed on the first nozzle is capable of heating the gas in the second nozzle to turn the longitudinal flame into an external flame in order to improve stability and resistance against the release of the longitudinal flame, so that the grate can stabilize the combustion process, even if the grate is located under a relatively low load (i.e. gas has a relatively low outlet flow). Secondly, the lateral flame formed on the first nozzle can occupy the space between two adjacent ignition matrices or the space between two adjacent grates for more efficient use of air in these spaces, making the combustion process more complete and the distribution of the flame more uniform, which results in leads to improved combustion efficiency of the grate. Thirdly, the air supplied to the device for adjusting the air intake can flow out of the space between two adjacent grates to prevent incomplete combustion of gas due to insufficient air. By controlling the device for adjusting the air intake, the air flow can be adjusted to ensure complete combustion of the gas, in other words, it is possible to further ensure the combustion efficiency of the grate.

Brief Description of the Drawings

In FIG. 1 is a structural schematic view illustrating a gas burner in accordance with an embodiment of the present invention.

In FIG. 2 is a schematic view showing the upper end surface of a gas burner in accordance with an embodiment of the present invention.

In FIG. 3 is an enlarged view of region A shown in FIG. 2.

In FIG. 4 is a schematic view showing the grate shown in FIG. 2, perspective view B.

In FIG. 5 is a schematic view showing the combustion of the grate shown in FIG. four.

Description of Reference Positions:

1 - frame of the main body; 11 - inlet for gas; 12 - tapering conical tube; 13 - tube with a hidden neck for discharge; 14 - diffusion tube; 15 - U-shaped outlet pipe; 16 - a distribution tube; 17 - supporting frame; 18 - a device for adjusting the air intake; 2 - grate; 21 - ignition matrix; 22 - the first nozzle; 23 - the second nozzle; 24 - side flame; 25 - longitudinal flame; 3 - a device for supplying gas; a is gas and b is air.

Detailed Description of Preferred Embodiments

Illustrative embodiments of the present invention will be described later in this document with reference to the drawings.

As shown in FIG. 1-5, a gas burner is provided. The gas burner contains a frame 1 of the main body and a row of grate 2 separated from each other and arranged in a row along the width of the grate 2 on the upper part of the frame 1 of the main body. A row of ignition matrices 21 is located on the upper end surface of each of the row of grate 2, and a row of ignition matrices 21 is aligned along the length of the grate 2 at least in one line. The ignition matrix 21 comprises two first nozzles 22 and at least one second nozzle 23. The first nozzle 22 is capable of forming a side flame 24 along its edge. The second nozzle 23 is capable of forming a longitudinal flame 25 in its upper direction. The two first nozzles 22 are located opposite each other, the length direction of each of the first two nozzles 22 corresponds to the length direction of the grate 2, and the second nozzle 23 is located between the first two nozzles 22. The gas “a” discharged from the first and second nozzles can be ignited with the formation of a blazing flame. The first nozzle 22 is capable of forming a side flame 24 along its edge by discharging the gas “a” in the lateral direction, and the second nozzle 23 is configured to form a longitudinal flame 25 in its upper direction by discharging the gas “a” upward. The longitudinal flame 25 serves as the main source of heat for its good stability and high temperature. With a configuration in which the first two nozzles 22 are located opposite each other and the second nozzle 23 is located between the two first nozzles 22, the flame formed by the ignition matrix 21 has a W-shape similar to the shape of a sunflower. This configuration has the following advantages. Firstly, the side flame 24 formed on the first nozzle 22 is capable of heating the gas “a” in the second nozzle 23 to turn the longitudinal flame 25 into an external flame in order to improve stability and resistance against tempering of the longitudinal flame 25, so that the grate 2 stabilize the combustion process, even if the grate 2 is under a relatively low load (i.e., the gas is characterized by a relatively low output stream). For example, if the load is relatively low, the longitudinal flame 25 is relatively small, and at the same time, the part of the side flame 24 directed to the second nozzle 23 can protect the lower part and the base of the longitudinal flame 25, so that the resistance against tempering of the longitudinal flame 25 can be improved to ensure the stability of the longitudinal flame 25. As another example, if the load is relatively high, both the side flame 24 and the longitudinal flame 25 are relatively large in size and at the same time the portion of the side flame 24 directed to the second nozzle 23 can form a flame in a C-shape or in the form opposite to the C-shape, attaching to the longitudinal flame 25 so that the lateral dispersion of the longitudinal flame 25 is not excessive, and both types the flames within the ignition matrix will be more homogeneous as a whole in order to improve the combustion efficiency of the entire grate 2. Secondly, the side flame 24 formed on the first nozzle 22 can occupy the space between vumya adjacent matrices ignition or the space between two adjacent grate 2 for more efficient use of the air in these spaces, making the combustion process is more complete and more uniform distribution of the flame, which results in improving the efficiency of combustion grate. Thirdly, the air supplied to the device 18 for adjusting the air intake can flow out of the space between two adjacent grates 2 to prevent incomplete combustion of the gas "a" due to insufficient air. By controlling the device 18 for adjusting the air intake, the air flow can be adjusted to ensure complete combustion of the gas, in other words, it is possible to further ensure the combustion efficiency of the grate 2.

In one embodiment, the first nozzle 22 is a rectangular nozzle or a trapezoidal nozzle, while the first nozzle 22 is equipped with a gas horn on each of the four sides of the first nozzle 22 to form a side flame 24 along its edge. The second nozzle 23 is a cylindrical nozzle with a gas horn on the upper part of the second nozzle 23 to form a longitudinal flame 25 in its upper direction. Both the first nozzle and the second nozzle extend 0.5-1 mm above the upper end surface of the grate. In addition, the area between two adjacent ignition matrices 21 on the upper end surface of the grate 2 is equipped with two second nozzles 23 to increase the thermal power of the grate 2.

In one embodiment, the frame 1 of the main body is equipped with at least two supporting frames 17 and a number of grate 2 installed on at least two supporting frames 17 side by side and separated from each other. Each of the at least two support frames is equipped with a series of gas pipes for supplying gas “a”, which correspond exactly to a number of grate grids 2 and are accordingly connected to a number of grate grates 2. The lower part of the frame 1 of the main body is equipped with a gas inlet 11 made with the possibility of connection with a device 3 for supplying gas, while the frame 1 of the main body is additionally equipped with a tapering conical tube 12, a tube with a hidden neck for discharge 13, a diffusion tube 14, U an outlet pipe 15 and a distribution pipe 16 connected in series between the gas inlet 11 and the grate 2, and the distribution pipe 16 is equipped with a series of gas outlets. Using the gas outlet, gas “a” can be supplied to the grate 2 through a gas pipe. When supplying gas to the gas inlet 11 using the gas supply device 3, a certain amount of air “b” can enter the gas inlet 11, mixing with the gas “a” to form a mixed gas (this can accelerate the gas burning speed “a” "In accordance with the basic idea of combustion). Then the mixed gas can flow through a tapering conical pipe 12, a pipe 13 with a hidden discharge neck, a diffusion pipe 14, a U-shaped outlet pipe 15, a distribution pipe 16 and a gas pipe in series, enter the grate 2 and be discharged from the first and second nozzles 22, 23 on the grate 2 for combustion to form a flame.

Based on the experiments carried out for a gas burner in accordance with the present invention, only 8-15 grate grids are needed to obtain a thermal power that matches or exceeds the thermal power of a traditional gas burner. Thus, the gas burner in accordance with the present invention has higher energy efficiency and lower cost.

Technical features of the above embodiments may be combined arbitrarily. For a brief summary of the description, not all possible combinations of technical features of the above embodiments have been described, but it will be obvious that these possible combinations are included in the scope of the present invention, unless there is a contradiction between the technical features.

The above preferred embodiments of the present invention are described in detail and should not be construed as limiting the scope of the present invention. It should be noted that variations and improvements will be apparent to those skilled in the art to which the present invention relates without departing from the spirit and scope of the invention. Therefore, the scope of the present invention is defined by the attached claims.

Claims (7)

1. A gas burner containing a frame of the main body, a row of grate grids separated from each other and arranged in a row on the upper part of the frame of the main body, characterized in that a number of ignition matrices are located on the upper end surface of each of the grate grates, a number of ignition matrices are aligned along the length of the grate at least in one line; the ignition matrix contains two first nozzles and at least one second nozzle, each of the first two nozzles is configured to form a side flame along its edge, the second nozzle is configured to form a longitudinal flame in its upper direction, the first two nozzles are located opposite each other, the length direction of each of the first two nozzles corresponds to the length direction of the grate, and the second nozzle is located between the two first nozzles; On the bottom of the frame of the main body there is a device for adjusting the air intake. 2. A gas burner according to claim 1, characterized in that the first nozzle is a rectangular nozzle or a trapezoidal nozzle, while the first nozzle is equipped with a gas horn on each of the four sides of the first nozzle, and the second nozzle is a cylindrical nozzle with a gas horn on top of the second nozzle. 3. A gas burner according to claim 2, characterized in that both the first nozzle and the second nozzle extend 0.5-1 mm above the upper end surface of the grate. 4. Gas burner according to claim 1, characterized in that the second nozzle is additionally located in the region between two adjacent ignition matrices on the upper end surface of the grate. 5. Gas burner according to any one of paragraphs. 1-4, characterized in that the frame of the main body is equipped with at least two supporting frames, and a number of grate, separated from each other, is installed on at least two supporting frames side by side. 6. The gas burner according to claim 5, characterized in that each of at least two of the supporting frames is equipped with a number of gas pipes having an exact correspondence with a number of grates. 7. Gas burner according to any one of paragraphs. 1-4, characterized in that the lower part of the frame of the main body is equipped with an inlet for gas, made with the possibility of connection with a device for supplying gas, while the frame of the main body is additionally equipped with a tapered conical tube, a tube with a hidden neck for discharge, a diffusion tube, A U-shaped outlet pipe and a distribution pipe connected in series between the gas inlet and the grate, and the distribution pipe is equipped with a series of outlet openings for ase, which are precisely matched with several grids.

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