KR102256870B1 - gasification burner for biomass - Google Patents

Abstract

The present invention relates to a biomass gasification burner. The present invention comprises a housing unit, a fuel supply unit, a combustion unit, a guide unit, and an operation unit. The present invention enables complete combustion as well as continuously maintaining an optimal combustion state.

Description

Gasification burner for biomass

The present invention relates to a biomass gasification burner, and more particularly, to a biomass gasification burner capable of completely burning fuel by continuously maintaining an optimum combustion state.

The fuel that led industrialization for the first time was not wood that mankind has been using for a long time, but coal that has stronger thermal power and can be easily collected in large quantities, followed by oil and natural gas, which are important sources of energy that mankind can use. Has been.

However, these resources, commonly referred to as fossil fuels, not only cause various environmental pollution, but are now depleted, and the development of new energy sources is urgent.

In this situation, biomass, energy produced by recycling biological organic resources such as wood, which was mainly used in the past, such as wood, crops, algae, plankton, and biological waste, is chemical fuel due to irreversible consumption of resources and accumulation of carbon dioxide. Technology related to this is being researched as it is useful as a renewable resource in the future that can substitute for.

Moreover, in the use of biomass, the gasification method that produces high-quality fuel with high efficiency consisting of gases other than the combustion method or liquid bio-oil, when applied to the power generation system, produces less carbon dioxide emissions and pollution to the outside. It can be said to be a highly anticipated field as a way to reduce material emissions.

Biomass used for gasification and decomposition power generation is unused wood-based and herbaceous systems, including waste wood and its by-products, and tropical agricultural by-products such as palm oil extraction waste, coconut husk, rice husk, and corn stalk. In terms of carbon-neutral energy, recently attracting great attention, its usage performance continues to increase in the fields of processing agricultural products to turn them into liquid fuels and in the fields of heat energy recovery by direct combustion.

In particular, in the field of heat energy recovery, it has been a method used by mankind for thousands of years, and recently, biomass has been used as a raw material for cogeneration, replacing fossil fuels to produce electricity and heat.

On the other hand, compared to the method of co-generation with steam produced by directly burning biomass, the biomass gasification and decomposition device produces a synthetic gas of carbon monoxide and hydrogen by incomplete combustion and uses it as a fuel for an engine generator. Because it can be produced, biomass is abundant, but in rural or remote villages in tropical agricultural countries where electric energy is insufficient, gasification is a way to obtain electricity easily. It is a useful technique that attracts attention from the side.

The biggest problem of the biomass gasification and decomposition device, which is simply manufactured on a small scale, is that the shape of the raw material is very diverse depending on the pretreatment method as well as the shape of the biomass itself, and there is no flow due to strong frictional force, and the change in heat capacity due to various densities. As an unspecified factor in controlling the rate of raw material input and the discharge of burned ash in the gasification decomposition device, it hindered the maintenance of the accurate operation speed, and for this reason, it has been a major obstacle to the commercialization of gasification power generation devices.

Existing biomass gasification and decomposition devices are largely introduced into three classification methods according to the flow method of the combustion gas. The first method is a down draft method. In a small device that uses less raw materials, the flow of combustion gas escapes from the top to the bottom, and the high-temperature contact time and the contact effect with unreacted carbon are lengthened, so that carbon dioxide is reduced to carbon monoxide. The emphasis is on making this work well.

The second method is called the up-draft method. In a large-scale (normally 1MW or more) device where a large amount of raw materials are used, the flue gas flow naturally flows from the bottom to the top, allowing a large amount of air to easily pass through the gasification and decomposition unit. Therefore, instead of making the combustion speed faster, a design has been mainly proposed in which tar with a large amount of production can be refined well at the rear stage.

As a third method, fluid bubbled gasification (FBG) has been proposed in order to burn large quantities of materials with low specific gravity such as rice husk and sawdust.

Conventional techniques mainly include air supply and combustion chamber design method to improve combustion performance (Korean Patent Registration No. 10-0955591, Rural Development Administration of Korea), and a two-stage combustion method that provides high thermal efficiency (Korean Patent Publication No. 10- 2006-0044509, Zaidan Hosing Denryokuchuokkenkyusho), as well as gasifiers and power generation devices that have already developed various technologies, to form a more efficient system, produce high-quality gas, effectively use waste heat, and cool water. In addition, there has been a continuing desire to develop advanced technologies that enable effective circulation.

Accordingly, an object of the present invention is to provide a biomass gasification burner capable of realizing complete combustion by combusting fuels under the best conditions of various fuels.

Another object of the present invention is to provide a biomass gasification burner capable of continuously maintaining the best combustion conditions by inducing the optimum 3T (Time, Temperature, turbulence).

In order to achieve the above object, the biomass gasification burner of the present invention has a housing portion in which a front plate is coupled to a housing and a center hole is drilled in the center of the front plate, but the inner periphery of the center hole is cut to form an air passage, and the The main supply pipe is passed through the center hole of the front plate of the housing part, and the discharge pipe of the hopper is vertically penetrated into the housing to communicate the discharge pipe to the main supply pipe, but a supply screw is formed inside the main supply pipe and a rotating gear is attached to the rear end of the supply screw. A fuel supply unit and a combustion unit that penetrates the combustion drum through the front plate of the housing unit and couples a rotation gear to the rear end of the combustion drum to interlock with the air drum receiving the combustion drum to the front plate, and the combustion unit It is composed of a guide unit that smoothly rotates the combustion drum and smoothly supplies air to the air drum, and an operation unit that controls the rotation of the combustion drum and fuel supply by controlling the supply screw of the combustion drum and the fuel supply unit of the combustion unit. It is a basic feature in its technical configuration.

Therefore, the biomass gasification burner of the present invention continuously supplies fuel to the inside of the combustion drum while the supply screw rotates by the gear ratio and rotates in conjunction with the combustion drum to sufficiently continuously mix the fuel and at the same time into the air drum. By supplying air, the air is discharged through the rotation guide spiral and the air discharge hole of the combustion drum, leading to more efficient mixing of fuel, and at the same time inducing the smooth discharge of residues such as ash after combustion, thus ensuring the optimum combustion state. It is to be able to keep continuously, and not only allows complete combustion by burning the fuel in the best condition, but also has the effect of improving the trust in the product because it continuously maintains the optimal combustion state.

1 is an overall perspective view illustrating a biomass gasification burner according to the present invention.
Figure 2 is an overall side view showing to explain the biomass gasification burner according to the present invention
3 is a perspective view showing a front part of the biomass gasification burner according to the present invention.
4 is a perspective view illustrating a guide part of a biomass gasification burner according to the present invention.
5 is a perspective view showing a rear portion of the biomass gasification burner according to the present invention.
6 is a side view showing a rear portion of the biomass gasification burner according to the present invention.
7 is an exploded perspective view showing a front portion of the biomass gasification burner according to the present invention.
8 is an exploded perspective view showing a rear portion of the biomass gasification burner according to the present invention.
9 is an exploded perspective view showing a rear portion of the biomass gasification burner according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 9, in the biomass gasification burner 100 of the present invention, a front plate 115 is coupled to a cylindrical housing 111, and a center hole 116 is formed in the center of the front plate 115. The main supply pipe (110) in which the inner periphery of the center hole 116 is cut to form an air passage (116a) and the center hole (116) of the front plate (115) of the housing part (110) 123) and vertically through the discharge pipe 122 of the hopper 121 through the housing 111 to communicate the discharge pipe 122 to the main supply pipe 123, but the supply screw 124 inside the main supply pipe 123 The fuel supply unit 120 to which the rotation gear 126 is attached to the rear end of the supply screw 124 and the combustion drum 131 is passed through the front plate 115 of the housing unit 110 and the combustion drum ( A combustion unit 130 that couples the rotary gear 133 to the rear end of the 131 and interlocks with the air drum 138 accommodating the combustion drum 131 to the front plate 115, and the combustion unit A guide unit 140 for smoothly rotating the combustion drum 131 of 130 and supplying air to the air drum 138 smoothly, and the combustion drum 131 and the fuel supply unit of the combustion unit 130 ( It consists of an operation unit 150 that controls the supply screw 124 of the 120) to smoothly control the rotation of the combustion drum 131 and supply of fuel.

The housing unit 110 is provided with a cylindrical housing 111, a vertical through hole 112 is drilled at the top and a rear plate 113 having an air supply hole 114 drilled at the rear is attached, but the air supply hole ( It is preferable to combine a conventional air supply means (not shown) such as a fan to 114).

Further, the front plate 115 is coupled to the front of the housing 111, a center hole 116 is drilled in the center of the front plate 115, and the inner periphery of the center hole 116 is cut to open the air passage 116a. The air control plate 117 and the control handle 118 are mutually interlocked to each other before and after the control hole 116b is drilled in a circular arc at a predetermined position, and the air passage 116a is opened and closed at the same time. Although it is desirable to be able to efficiently control the amount of air supplied, a conventional opening/closing means or the like can be selected and used as necessary.

The fuel supply unit 120 penetrates the main supply pipe 123 through the center hole 116 of the front plate 115 of the housing 111 to supply fuel into the combustion drum 131, but the housing 111 The discharge pipe 122 of the hopper 121 is passed through the vertical through hole 112 to communicate with the main supply pipe 123 so that fuel can be continuously supplied.

Moreover, by inserting the supply screw 124 into the main supply pipe 123 and attaching the rotary gear 126 to the rear shaft 125 of the supply screw 124, the supply screw 124 is rotated by the rotation of the rotary gear 126. ) Is rotated, so it is ideal to continuously and accurately supply a certain amount of fuel.

The combustion unit 130 penetrates the rear portion of the cylindrical combustion drum 131 through the front plate 115 of the housing 111 and couples the rotation gear 133 to the rear end of the combustion drum 131 to rotate and interlock. However, it is preferable to perforate a plurality of air discharge holes 132 in the combustion drum 131 to form a porous shape, and to puncture the air discharge holes 132 obliquely forward so as to guide them forward in the discharge direction of air.

In addition, a through hole 134 is formed in the center of the rotating gear 133 to penetrate the main supply pipe 123 of the fuel supply unit 120, and a plurality of air passages ( 135) and the fastening hole 136 are drilled, and the connecting member 137 is attached to the rear end of the combustion drum 131 to couple the connecting member 137 to the fastening hole 136, and the combustion drum 131 and the rotating gear ( 133) can be linked.

On the other hand, the rear end of the air drum 138 is coupled to the front plate 115 to accommodate the combustion drum 131 therein, but a rotation guide spiral piece 139 is formed on the inner periphery of the air drum 138 and is at the front end. It is preferable to attach a blocking member (138a) to apply a rotational force to the incoming air to a certain extent and to maintain a minute distance from the combustion drum (131) so that the combustion drum (131) rotates smoothly.

The guide part 140 couples the guide hole 141 to the rear of the rotation gear 133 of the combustion part 130, but passes the guide hole 141 through the main supply pipe 123, and the guide hole 141 and the main supply pipe (123) It is combined with the bearing 143 and the bushing 144 to induce smooth rotation of the rotary gear 133, so that the combustion drum 131 coupled to the rotary gear 133 is also interlocked to rotate smoothly. will be.

Here, an air passage 142 is formed between the rear surface of the rotating gear 133 and the guide hole 141 to prevent air through the air passage 135 of the rotating gear 133 and the air passage 116a of the front plate 115. It is possible to smoothly supply air to the drum 138.

The operation unit 150 includes a drive motor 151 and attaches the main gear 152 to the rotation shaft of the drive motor 151, but is coupled to the shaft 125 of the main gear 152 and the supply screw 124. The combustion drum 131 and the supply screw 124 are rotated by the rotation of the main gear 152 by gear-coupled to the rotating gear 126 and gear-coupled to the rotating gear 133 of the combustion drum 131 by the power transmission gear 153. It is desirable to be able to interlock at the same time.

Here, the power transmission gear 153 is coupled to both ends of the shaft 154 to transmit power to the rotating gear 133 at a distance, but various gear trains can be selectively applied. It is ideal to set the gear ratio in consideration, but to set the rotation of the supply screw 124 faster than the rotation of the combustion drum 131.

On the other hand, the operation unit 150 is provided with a plurality of guide pipes 155 and is provided with a support tool 156 penetrating the guide pipe 155 to be coupled to the outer periphery of the main supply pipe 123, but the guide pipe 155 It is preferable to install a device (not shown) for ignition or temperature observation by placing the front end of the inside of the combustion drum 131.

The operation of the present invention will be described as follows.

First, the combustion drum 131 is sufficiently filled with fuel and then the main gear 152 is rotated by controlling the driving motor 151 in the ignited state. Since 133 rotates at the same time, the supply screw 124 and the combustion drum 131 are also interlocked to rotate at a constant rate at the same time.

At this time, while rapidly rotating the supply screw 124 several times due to the gear ratio, various fuels selected into the combustion drum 131 are continuously supplied through the main supply pipe 123.

At the same time, the combustion drum 131 is also interlocked to gradually rotate, and the fuel in the combustion drum 131 is continuously mixed sufficiently.

In this state, when air is supplied into the air drum 138, the air is discharged into the combustion drum 131 through the rotation guide spiral piece 139 and the air discharge hole 132 of the combustion drum 131, thereby efficiently discharging fuel. At the same time as mixing, since it induces to smoothly discharge residues such as ash to the outside after combustion, the optimum combustion state can be maintained continuously.

In the above description, the present invention has been illustrated and described in connection with specific embodiments, but it is understood that various modifications and changes are possible within the scope of the spirit and scope of the invention indicated by the claims. Anyone who has it will be easy to know.

100: gasification burner 110: housing part
111: housing 112: vertical through hole
113: rear plate 114: air supply hole
115: front plate 116: center hole
116a: air passage 116b: control length
117: air control plate 118: control handle
120: fuel supply unit 121: hopper
122: discharge pipe 123: main supply pipe
124: supply screw 125: shaft
126: rotation gear 130: combustion part
131: combustion drum 132: air discharge hole
133: rotating gear 134: through hole
135: air passage 136: fastening hole
137: connecting member 138: air drum
138b: blocking member 139: rotation guide spiral piece
140: guide part 141: guide hole
142: air passage 143: bearing
144: bushing 150: operating part
151: drive motor 152: main gear
153: power transmission gear 154: shaft
155: connector 156: support

Claims (5)

A housing portion in which the front plate 115 is coupled to the housing 111 and a center hole 116 is drilled in the center of the front plate 115, but the inner periphery of the center hole 116 is cut to form an air passage 116a (110) Wow,
The main supply pipe 123 is passed through the center hole 116 of the front plate 115 of the housing unit 110 and the discharge pipe 122 of the hopper 121 is vertically passed through the housing 111 so that the discharge pipe 122 A fuel supply unit 120 in which a supply screw 124 is formed in the main supply pipe 123 and a rotation gear 126 is attached to the rear end of the supply screw 124,
The combustion drum 131 is passed through the front plate 115 of the housing unit 110 and the rotary gear 133 is coupled to the rear end of the combustion drum 131 to interlock and accommodate the combustion drum 131 therein. A combustion unit 130 that couples the air drum 138 to the front plate 115,
A guide unit 140 for smoothly rotating the combustion drum 131 of the combustion unit 130 and smoothly supplying air to the air drum 138, and
It is characterized by consisting of an operation unit 150 for controlling the rotation of the combustion drum 131 and fuel supply by controlling the combustion drum 131 of the combustion unit 130 and the supply screw 124 of the fuel supply unit 120 Biomass gasification burner.
The method of claim 1,
The housing unit 110 has a cylindrical housing 111, a vertical through hole 112 is drilled at the top, and a rear plate 113 having an air supply hole 114 is attached to the rear, and the housing 111 ) To the front plate 115 of the control hole (116b) in an arc in the shape of an arc, and open and close the air passage (116a) by interlocking the air control plate (117) and the control handle (118) before and after the control hole (116b) Biomass gasification burner, characterized in that configured to control the amount.
The method of claim 1,
The combustion unit 130 is formed in a porous shape by drilling a plurality of air discharge holes 132 in the combustion drum 131, but the air discharge hole 132 is obliquely drilled forward to guide it forward in the discharge direction of air. And, a through hole 134 is formed in the center of the rotation gear 133 to penetrate the main supply pipe 123 of the fuel supply unit 120, and a plurality of air passages ( 135) and the fastening hole 136 are drilled, and the connecting member 137 is attached to the rear end of the combustion drum 131 to couple the connecting member 137 to the fastening hole 136, and the combustion drum 131 and the rotating gear ( 133) can be interlocked, a rotation guide spiral piece 139 is formed on the inner periphery of the air drum 138, and a blocking member 138a is attached to the front end to apply rotational force to the incoming air and at the same time, the combustion drum ( Biomass gasification burner, characterized in that the combustion drum 131 is configured to rotate smoothly by maintaining a finely separated state from the 131.
The method of claim 1,
The guide part 140 couples the guide hole 141 to the rear of the rotation gear 133 of the combustion part 130, but passes the guide hole 141 through the main supply pipe 123, and the guide hole 141 and the main supply pipe (123) is combined with a bearing 143 and a bushing 144 to smoothly rotate the rotating gear 133, and an air passage 142 is formed between the rear surface of the rotating gear 133 and the guide hole 141 Biomass gasification burner, characterized in that configured to.
The method of claim 1,
The operation unit 150 includes a drive motor 151, attaches the main gear 152 to the rotating shaft of the drive motor 151, and is coupled to the shaft 125 of the main gear 152 and the supply screw 124. The combustion drum 131 and the supply screw 124 are rotated by the rotation of the main gear 152 by gear-coupled to the rotating gear 126 and gear-coupled to the rotating gear 133 of the combustion drum 131 by the power transmission gear 153. However, the rotation of the supply screw 124 is set faster than the rotation of the combustion drum 131, and a support tool for penetrating the guide tube 155 while having a plurality of guide tubes 155 ( 156), characterized in that the biomass gasification burner.

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