CN215570521U - High-efficiency energy-saving incinerator soot blower - Google Patents

Abstract

The utility model relates to the technical field of boiler cleaning, in particular to a high-efficiency energy-saving incinerator soot blower, which is characterized by comprising the following components: one end of the ignition tube is provided with an ignition part; an igniter disposed within the ignition portion; and the gas storage bag is arranged at the other end of the ignition tube, the gas storage bag stores the combustible mixed gas conducted by the ignition tube, and the igniter obtains an ignition signal to ignite the combustible mixed gas in the gas storage bag so as to explode the gas storage bag. Can hand the removal through setting up the ignition tube, be convenient for stretch into furnace or pipeline and carry out the fixed point explosion and clear up the ashes, set up the gas storage package and store appropriate amount combustible gas mixture and ignite the explosion, the explosive power is big, the energy saving again.

Description

High-efficiency energy-saving incinerator soot blower

Technical Field

The utility model relates to the technical field of boiler cleaning, in particular to a high-efficiency and energy-saving incinerator soot blower.

Background

The fluidized bed is used for waste incineration, burns rubbish and produces the ashes and need in time be carried and leave furnace, however in current production process, firstly furnace deposition influences the quality of burning easily, and secondly conveying line deposition influences the transport and causes the putty, and the urgent need can conveniently be directed against the instrument of the different region operation of carrying out the deashing.

In a fuel gas pulse soot blower disclosed in patent application No. CN201920635664.3, an air outlet end of an air compressor is communicated with an air inlet end of an air flow meter through a first gate valve, an air outlet end of the air flow meter is communicated with an air inlet end of a first electromagnetic valve through a pipeline, and an air outlet end of the electromagnetic valve is correspondingly communicated with an air inlet at the top of a mixing tank; the gas outlet end of the combustible gas tank is correspondingly communicated with the gas inlet end of the combustible gas flowmeter through a second gate valve, the gas outlet end of the combustible gas flowmeter is correspondingly communicated with the gas inlet end of a second electromagnetic valve through a pipeline, and the gas outlet end of the electromagnetic valve is correspondingly communicated with the combustible gas inlet in the middle of the mixing tank through a pipeline; the bottom of the mixing tank is correspondingly communicated with the gas storage tank through a pipeline, the middle of the tank body of the gas storage tank is provided with an ignition port, and the electromagnetic valve, the air flow meter and the combustible gas flow meter are controlled by a gas circuit control system.

The inventor has the following problems in the using process: 1. the gas pulse device is fixedly arranged on the hearth, cannot move to blow and clean ash, and has poor effect; 2. the gas pipe is directly communicated with the hearth, and the problems of combustible gas dissipation and small explosion vibration force are solved.

SUMMERY OF THE UTILITY MODEL

Aiming at the problems, the utility model provides a high-efficiency energy-saving incinerator soot blower which can be moved by hand through an ignition pipe, is convenient to stretch into a hearth or a conveying pipeline for fixed-point explosion and cleaning of furnace ash, is provided with a gas storage bag for storing a proper amount of combustible mixed gas to ignite and explode, has large explosive force and saves energy, and solves the problems that in the background technology, a gas pulse device is fixedly arranged on the hearth, cannot move to blow and clean the soot, has poor effect, is directly communicated with the hearth through a gas pipe, and has small explosive vibration force due to the escape of the combustible gas.

In order to achieve the purpose, the utility model provides the following technical scheme:

an energy-efficient burns burning furnace soot blower, its characterized in that includes:

one end of the ignition tube is provided with an ignition part;

an igniter disposed within the ignition portion; and

the gas storage bag is arranged at the other end of the ignition tube, the gas storage bag stores the combustible mixed gas conducted by the ignition tube, and the igniter obtains an ignition signal to ignite the combustible mixed gas in the gas storage bag to explode the gas storage bag.

As an improvement, a straight-through joint is arranged on the ignition tube, and the straight-through joint can be connected with an extension tube for extending the ignition tube.

As a refinement, the diameter of the ignition part is greater than or equal to the diameter of the middle part of the squib.

As an improvement, the gas storage bag comprises a sealing bag and a protection bag sleeved outside the sealing bag.

As an improvement, the bag openings of the sealing bag and the protection bag are sleeved on the ignition tube and are bound with the ignition tube.

As an improvement, the protection bag is a cloth bag, and the cloth bag is covered on the outer side of the sealing bag after being wetted.

As an improvement, the ignition device further comprises a gas distribution station and an electric cabinet, wherein the gas distribution station is used for configuring combustible mixed gas and conveying the combustible mixed gas to the ignition pipe through a guide pipe communicated with the ignition part, and the electric cabinet is electrically connected with the igniter to control the igniter to work.

As an improvement, the gas distribution station comprises:

the gas conveying set comprises a flame arrester I, a pressure regulating valve, a gas flowmeter and a check valve which are linearly connected by a pipeline along the airflow flowing direction, wherein the gas flowmeter measures the conveyed gas quantity;

the combustion-supporting conveying group comprises a pressure regulating valve, a pressure gauge and an air flow meter which are linearly connected by a pipeline along the air flow flowing direction, and the air flow meter measures the conveyed combustion-supporting air quantity; and

and the mixing tank is arranged at the tail parts of the gas conveying group and the combustion-supporting conveying group and is used for mixing gas and combustion-supporting gas.

As an improvement, a second fire arrester is arranged at the end part of the conduit leading into the ignition part of the mixing tank, and the second fire arrester prevents a fire source in the ignition pipe from reversely igniting the mixed gas in the mixing tank.

As an improvement, the electric control box is electrically connected with the gas flow meter and the air flow meter and used for parameter setting and data display.

The utility model has the beneficial effects that:

(1) the ignition tube can be moved by hand, so that the ignition tube can conveniently extend into a hearth or a conveying pipeline to perform fixed-point explosion and clean furnace dust, the gas storage bag is arranged to store a proper amount of combustible mixed gas to ignite and explode, the explosive force is large, and the energy is saved;

(2) the direct joint is arranged to be connected with the lengthening pipe, so that the ash removal device can adapt to the fixed-point ash removal of a deeper hearth;

(3) the gas storage bag comprises the sealing bag and the protection bag sleeved outside the sealing bag, the protection bag is soaked with water in advance to prevent the sealing bag from melting due to high temperature, and the structure is simple and reliable.

In conclusion, the utility model has the advantages of good ash removal effect, simplicity, reliability, fixed-point ash removal and the like, and is particularly suitable for the technical field of boiler cleaning.

Drawings

FIG. 1 is a schematic view of the structure of the ignition tube and gas storage bag combination of the present invention;

FIG. 2 is a schematic structural view of a gas distribution station and an electric cabinet connected with an ignition tube;

fig. 3 is a schematic structural diagram of embodiment 2 of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the equipment or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

Example one

As shown in fig. 1 and 2, an energy-efficient incinerator sootblower is characterized by comprising:

the ignition device comprises an ignition tube 1, wherein one end of the ignition tube 1 is provided with an ignition part 11;

an igniter 2, the igniter 2 being provided in the ignition portion 11; and

the gas storage bag 3 is arranged at the other end of the ignition tube 1, the gas storage bag 3 stores the combustible mixed gas conducted by the ignition tube 1, and the igniter 2 obtains an ignition signal to ignite the combustible mixed gas in the gas storage bag 3 to explode the gas storage bag 3.

It should be noted that the ignition tube 1 is a handheld portable tube, and is manually held to a part such as a hearth, a conveying pipe or a bin pump, which needs to be cleaned, the end of the ignition tube 1 is wrapped by the gas storage bag 3 and is inserted into the part needing to be cleaned, the igniter 2 is ignited to explode the gas storage bag 3, and the gas pressure vibration generated by the explosion is used for cleaning furnace ash.

Further, the diameter of the ignition portion 11 is greater than or equal to the diameter of the middle portion of the squib 1.

It should be noted that, the igniter 2 is placed in the ignition portion 11 for electrically controlled ignition, and the ignition portion 11 has a large diameter and stores a large amount of combustible gas, so as to facilitate ignition.

Further, the gas storage bag 3 comprises a sealing bag 31 and a protection bag 32 sleeved outside the sealing bag 31.

Further, the sealing bag 31 and the protecting bag 32 have bag openings to sleeve the ignition tube 1 and to bind the ignition tube 1.

It should be noted that the sealing bag 31 is used for storing a set amount of combustible gas, a bag opening of the sealing bag is bound and sealed with the ignition tube 1, and a sealed space formed by the sealing bag 31 is sufficient for the combustible gas to be used for subsequent ignition and detonation.

Further, the protection bag 32 is a cloth bag, and the cloth bag is covered on the outer side of the sealing bag 31 after being wetted with water.

The protection bag 32 is wetted to protect the sealing bag 31 from melting the sealing bag 31 due to high temperature in the furnace, and the gas leakage is prevented from being detonated.

Further, the gas distribution station 4 is used for distributing combustible mixed gas and conveying the combustible mixed gas to the ignition tube 1 through a guide tube communicated with the ignition part 11, and the electric cabinet 5 is electrically connected with the igniter 2 to control the igniter 2 to work.

Further, the gas distribution station 4 includes:

the gas delivery group 41 comprises a flame arrester 411, a pressure regulating valve 412, a gas flow meter 413 and a check valve 414 which are linearly connected by pipelines along the gas flow direction, and the gas flow meter 413 measures the delivered gas quantity;

the combustion-supporting conveying group 42 comprises a pressure regulating valve 412, a pressure gauge 421 and an air flow meter 422 which are linearly connected by a pipeline along the air flow flowing direction, and the air flow meter 422 measures the conveyed combustion-supporting air quantity; and

and the mixing tank 43 is arranged at the tail parts of the gas conveying group 41 and the combustion-supporting conveying group 42 and is used for mixing gas and combustion-supporting gas.

It should be noted that the combustible gas is acetylene and the combustion-supporting gas is oxygen, and they are mixed in the mixing tank 43 in a predetermined ratio.

Further, the end of the conduit of the mixing tank 43, which leads into the ignition part 11, is provided with a second flame arrester 44, and the second flame arrester 44 prevents the fire source in the ignition tube 1 from reversely igniting the mixture in the mixing tank 43.

Further, the electric control box 5 is electrically connected to the gas flow meter 413 and the air flow meter 422 for parameter setting and data display.

It should be noted that the gas flow meter 413 and the air flow meter 422 are set by parameters of the electric cabinet 5, and a mixing ratio is preset, so that shock wave vibration generated by induced explosion is facilitated.

Example two

As shown in fig. 3, in which the same or corresponding components as those of the first embodiment are denoted by the same reference numerals as those of the first embodiment, only the differences from the first embodiment will be described below for the sake of convenience: the second embodiment is different from the first embodiment in that:

in the present embodiment, the ignition tube 1 is provided with a through joint 12, and the through joint 12 can be connected with an extension tube for extending the ignition tube 1.

It should be noted that, when the ash removal treatment needs to be performed on a deeper or narrow space, the extension pipe is connected to the straight-through joint 12 and extends to a specified point to detonate for ash removal, so that the structure is convenient and quick to disassemble or assemble, and the ash removal effect is enhanced.

The working process is as follows:

establish gas storage package 3 with the exit end cover of ignition tube 1 and bind firmly, the gas of gas distribution station 4 simultaneously is carried group 41 and combustion-supporting transport group 42 and is mixed according to the proportion of quantitative transport combustible gas and combustion-supporting gas to blending tank 43 respectively, artifical handheld ignition tube 1 stretches into to the mechanism part that needs the deashing to handle, the gas that mixes is good is passed through pipe connection ignition tube 1 and is aerifyd in to gas storage package 3, gas storage package 3 has stored behind the combustible mixture of setting for the volume, 2 ignitions of electric cabinet 5 control point firearm, gas storage package 3 detonates in mechanism part, carry out the vibration deashing through the vibration shock wave.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. An energy-efficient burns burning furnace soot blower, its characterized in that includes:

the ignition device comprises an ignition tube (1), wherein one end of the ignition tube (1) is provided with an ignition part (11);

an igniter (2), wherein the igniter (2) is arranged in the ignition part (11); and

the ignition device comprises a gas storage bag (3), the gas storage bag (3) is arranged at the other end of the ignition tube (1), the gas storage bag (3) stores combustible mixed gas conducted by the ignition tube (1), and the igniter (2) obtains an ignition signal to ignite the combustible mixed gas in the gas storage bag (3) so as to explode the gas storage bag (3).

2. An energy-efficient incinerator sootblower as claimed in claim 1 wherein said igniters (1) are provided with a through connection (12) and said through connection (12) is connectable to an extension pipe for extending said igniters (1).

3. An energy efficient incinerator sootblower as claimed in claim 1 wherein said firing section (11) diameter is greater than or equal to the diameter of the middle of said firing pipe (1).

4. An energy-efficient incinerator sootblower as claimed in claim 1 wherein said gas storage bag (3) includes a sealing bag (31) and a protective bag (32) fitted over the outside of the sealing bag (31).

5. An energy-efficient incinerator sootblower as claimed in claim 4 wherein said sealing bag (31) and said protective bag (32) have their mouths engaging said ignitron (1) and binding said ignitron (1).

6. The efficient and energy-saving incinerator soot blower of claim 4, characterized in that said protection bag (32) is a cloth bag, and said cloth bag is covered outside said sealing bag (31) after being wetted with water.

7. An energy-efficient incinerator soot blower as claimed in claim 1 further comprising a gas distribution station (4) and an electric control box (5), said gas distribution station (4) being configured to distribute the combustible mixture and to deliver the combustible mixture to said igniter tube (1) through a conduit communicating with said igniter portion (11), said electric control box (5) being electrically connected to said igniter (2) to control the operation of said igniter (2).

8. An energy efficient incinerator sootblower as claimed in claim 7 wherein said gas distribution station (4) includes:

the gas delivery group (41) comprises a flame arrester I (411), a pressure regulating valve (412), a gas flow meter (413) and a check valve (414) which are linearly connected by a pipeline along the gas flow direction, and the gas flow meter (413) meters the delivered gas quantity;

the combustion-supporting conveying set (42) comprises a pressure regulating valve (412), a pressure gauge (421) and an air flow meter (422), wherein the pressure regulating valve, the pressure gauge and the air flow meter are linearly connected by a pipeline along the air flow circulation direction, and the air flow meter (422) is used for metering the conveyed combustion-supporting gas quantity; and

and the mixing tank (43) is arranged at the tail parts of the gas conveying group (41) and the combustion-supporting conveying group (42) and is used for mixing gas and combustion-supporting gas.

9. An energy-efficient incinerator sootblower as claimed in claim 8 wherein said mixing tank (43) end of conduit leading into said ignition section (11) is provided with a second flame arrestor (44), said second flame arrestor (44) preventing the fire source in said squib (1) from back igniting the mixture in said mixing tank (43).

10. An energy efficient incinerator sootblower as claimed in claim 8 wherein said electrical cabinet (5) electrically connects said gas flow meter (413) and said air flow meter (422) for parameter setting and data display.

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