KR20240000118A - A horizontal type boiler for waste fuel - Google Patents

Abstract

The present invention relates to a horizontal waste fuel boiler system, and more specifically, to a hot air boiler system integrated with a high-temperature combustion furnace using solid fuel such as RDF or RPF made from waste, with a T-type burner unit of a double structure. This relates to a horizontal waste fuel boiler system that minimizes the installation space of the boiler system by horizontally connecting the high-temperature combustion furnace and the hot air boiler, improves combustion efficiency of waste by supplying preheated air, and minimizes NOx generation by supplying steam.

Description

A horizontal type boiler for waste fuel}

The present invention relates to a horizontal waste fuel boiler system, and more specifically, to a hot air boiler system integrated with a high-temperature combustion furnace using solid fuel such as RDF or RPF made from waste, with a T-type burner unit of a double structure. This relates to a horizontal waste fuel boiler system that minimizes the installation space of the boiler system by horizontally connecting the high-temperature combustion furnace and the hot air boiler, improves combustion efficiency of waste by supplying preheated air, and minimizes NOX generation by supplying steam.

In general, when using oil boilers or electric boilers for internal heating in greenhouses or small factories in rural areas, there are many difficulties as heating costs increase when used for a long time due to high oil prices and high electricity costs.

Because of these problems, the demand for compact hot air boilers that are economical and easy to install using solid waste such as RDF and RPF, which turn waste into fuel, is rapidly increasing.

However, conventional hot air boilers generally use a vertical cyclone type combustion device. This vertical cyclone type combustion device performs combustion only with cold air supplied from a blower, so combustion efficiency is low and a large amount of harmful substances are produced due to incomplete combustion. Substances are discharged into the atmosphere, causing pollution problems.

In addition, in order to overcome this problem, the combustion chamber of the vertical cyclone combustion device is installed in multiple stages to increase combustion efficiency, or by adding air control means or hazardous substance purification equipment in the combustion chamber to reduce hazardous substances, vertical boilers or As the height of the combustion furnace increases, it is difficult to install it indoors, and a separate large outdoor space is required, which causes the size and cost to increase, and the installation and operating costs are increasing due to the separate hazardous substance purification facility.

Republic of Korea Patent Publication No. 10-0559745 Republic of Korea Patent Publication No. 10-0330814

In order to solve the above problems, the present invention solves limitations in installation height or installation space by minimizing the combustion chamber height or space, and reduces hazardous substance emissions through high combustion efficiency and minimization of NOx production at low cost without a separate preheating device. The technical task is to provide a horizontal waste fuel boiler system that can simply and inexpensively discharge the ash of burned waste.

The horizontal waste fuel boiler system of the present invention is

A high-temperature combustion furnace (100) that burns waste fuel;

A T-type burner unit 200 installed on the upper part of the high-temperature combustion furnace 100 to convert the flame rising from the high-temperature combustion furnace 100 into the horizontal direction;

A hot air boiler (300) connected horizontally to the rear of the T-type burner unit (200) to heat external air and supply hot air;

A steam generator 400 installed on the outer peripheral surface of the T-type burner unit 200 to generate steam with the heat of the flame of the high-temperature combustion furnace 100 and supply it to the high-temperature combustion furnace 100;

It is characterized by including .

In addition, the combustion chamber 102 of the high temperature combustion furnace 100 is formed in a cylindrical shape,

An upper flame outlet 101 is formed at the top of the combustion chamber 102 of the high-temperature combustion furnace 100, so that the flame of the combustion chamber 102 is supplied to the T-type burner unit 200 installed at the top,

A high-temperature air pipe 205 is disposed in a tangential direction on the lower side wall of the cylindrical combustion chamber 102, so that air from the high-temperature air pipe 205 is supplied to the cylindrical combustion chamber 102 while spirally rotating along the side wall of the cylindrical combustion chamber 102. It is a characteristic.

In addition, the T-type burner unit 200 of the present invention includes an external cylinder 201 through which external air passes,

It includes an inner tube (202) through which the flame of the high-temperature combustion furnace (100) passes,

The outer cylinder 201 and the inner cylinder 202 have an overall T-shaped structure having a vertical portion and a horizontal portion,

The inner tube 202 of the T-type burner unit 200 is formed so that the vertical part and the horizontal part vertically intersect, and one side of the horizontal part is closed and the other side connected to the hot air boiler 300 is open to form a flame discharge pipe 207. And

The outer cylinder 201 of the T-type burner unit 200 is formed to surround the inner cylinder 202 and forms a closed space between the outer cylinder 201 and the inner cylinder 202 through which external air passes.

In addition, a combustion furnace blower 203 and a low-temperature air pipe 206 are disposed on one side of the T-type burner unit 200 to supply external air to the external cylinder 201 to preheat it,

On the other side of the T-type burner unit 200, a high-temperature air pipe 205 is disposed to supply preheated external air to the combustion chamber 102 of the high-temperature combustion furnace 100, and the preheated air is supplied to the combustion chamber 102 as combustion air. supply,

The combustion furnace blower 203 is characterized by controlling the supply amount of external air to the control unit using a temperature sensor that detects the temperature of the combustion chamber 102.

In addition, the steam generator 400 of the present invention includes a steam water inlet 401 through which steam is introduced, a spiral steam pipe 402 surrounding the outer peripheral surface of the flame discharge pipe 207 of the T-type burner unit 200, and a high temperature combustion furnace ( It is characterized by including a steam supply pipe 403 that supplies high temperature steam to 100).

In addition, the hot air boiler 300 of the present invention is horizontally connected to the T-type burner unit 200,

A heat exchanger (310) in which a heat exchange center pipe (311) is disposed inside a cylindrical body and a plurality of heat exchange pipes (312) are disposed at equal intervals on the outer periphery of the heat exchange center pipe (311) and communicate with the heat exchange center pipe (311),

A blower (320) for the boiler that supplies external air,

A cold air supply pipe 321 disposed on one side of the heat exchanger 310 and supplying external air supplied by the boiler blower 320 to the space between the body of the hot air boiler 300 and the heat exchange pipe 312,

It is characterized by including a hot air supply pipe 340 disposed on the other side of the heat exchanger 310 to supply external air heated by the heat exchanger 310 to a demand destination.

In addition, the present invention is provided with an ash discharge cyclone (500) that is simply attached to the external side wall of the high-temperature combustion furnace (100),

The ash discharge cyclone 500 includes a swirling flow inducing portion 510, a cyclone forming portion 520 disposed below the swirling flow inducing portion 510, an ash falling portion 530 disposed below the cyclone forming portion 520, and , It includes an ash collection part 540 disposed below the ash falling part 530,

An elastic falling device 550 for discharging combustion ash is formed below the cyclone forming part 520, and when heavy combusting ash accumulated under the cyclone forming part 520 collects more than a certain weight, it is discharged to the ash falling part 530. The characteristic is that

In addition, the elastic falling device 550 of the present invention includes a rotatable support plate 551, one end of which is rotatably installed on the bottom plate 522 of the cyclone forming portion 520 to load combustion material;

a support bar 552, one end of which is rotatably connected to the pivotable support plate 551 and the other end rotatably installed on the inner wall of the ash falling portion 531 to support the pivotable support plate 551;

It is characterized in that one end is connected to one side of the support bar 552 and the other end is fixed to the inner wall surface 531 of the ash falling portion and includes an elastic spring 553 that elastically supports the support bar 552.

In addition, the control unit that controls the horizontal waste fuel boiler system detects the rotation frequency of the rotating support plate 551 or the support bar 552 of the elastic falling device 550 for a certain period of time to determine whether the waste is incompletely burned and the degree of incomplete combustion. Its characteristic is judgment.

The present invention is a double-structured T-type burner unit that horizontally connects the high-temperature combustion furnace and the hot air boiler to minimize the installation space by minimizing the height of the boiler system, and adjusts the installation direction of the T-type burner unit to control the high-temperature combustion furnace and the hot air boiler. This has the effect of allowing optimal use of the installation space by allowing the installation to be installed in accordance with the indoor space.

In addition, the present invention has the effect of improving combustion efficiency by preheating combustion air without a separate preheating device by allowing external air to be preheated while passing through the double-structured T-type burner unit and then supplied to the high temperature combustion furnace.

In addition, the present invention generates steam by installing a steam generator outside the flame discharge pipe of the T-type burner unit, and supplies the heated steam to the high-temperature combustion furnace to control the combustion temperature, thereby reducing NOX production, thereby reducing the emission of harmful substances. It works.

In addition, the present invention has the effect that the high-temperature combustion furnace itself functions as a cyclone, and by simply attaching a separate ash discharge cyclone to this high-temperature combustion furnace, dust or combustion ash from the high-temperature combustion furnace is efficiently separated and collected, thereby eliminating the need for a separate ash discharge facility. There is.

1 is a diagram showing the appearance of a horizontal waste fuel boiler system according to the present invention.
Figure 2 is a diagram explaining the interior of a horizontal waste fuel boiler system according to the present invention.
Figure 3 is a diagram explaining the inside of a T-type burner unit according to an embodiment of the present invention.
Figure 4 is a diagram explaining the interior of a hot air boiler according to an embodiment of the present invention.
Figure 5 is a diagram explaining the interior of an ash discharge cyclone according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings. The present invention may be subject to various changes and may have various forms, and should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention.

First, a horizontal waste fuel boiler system according to an embodiment of the present invention will be described with reference to FIGS. 1 and 2.

A horizontal waste fuel boiler system according to an embodiment of the present invention includes a high-temperature combustion furnace 100 that burns waste fuel such as RPF or wood pellets;

A T-type burner unit 200 of a double structure installed on the upper part of the high-temperature combustion furnace 100 to convert the flame rising from the high-temperature combustion furnace 100 into the horizontal direction;

A hot air boiler 300 that is horizontally connected to the rear of the T-type burner unit 200 to allow the flame of the high-temperature combustion furnace 100 to be input into the heat exchanger, and to supply hot air by heating air with the heat exchanger;

It includes a steam generator 400 installed on the outer peripheral surface of the T-type burner unit 200 to generate steam with the heat of the flame of the high-temperature combustion furnace 100 and supply it to the high-temperature combustion furnace 100.

In the high-temperature combustion furnace 100 of the present invention, waste fuel such as RPF or wood pellets is automatically supplied from the waste supply means 10 connected to the bottom, and the temperature of the combustion chamber 102 of the high-temperature combustion furnace 100 or the hot air boiler ( 300), the amount of waste supplied is adjusted according to the temperature, and the waste fuel is first burned through an external pilot burner.

An upper flame outlet 101 is formed at the top of the combustion chamber 102 of the high-temperature combustion furnace 100 so that the flame of the combustion chamber 102 is supplied to the T-type burner unit 200 installed at the top.

In addition, the combustion chamber 102 of the high-temperature combustion furnace 100 is formed in a cylindrical shape, and a high-temperature air pipe 205 is disposed in a tangential direction on the lower side wall of the cylindrical combustion chamber 102, so that the preheated air in the high-temperature air pipe 205 is cylindrical. It is supplied to the cylindrical combustion chamber 102 while spirally rotating along the side wall of the combustion chamber 102.

Due to this structure, the flame of the waste burned at the bottom of the cylindrical combustion chamber 102 rises, meets the swirling preheated air, forms a swirling flame, and is discharged through the upper flame outlet 101.

The high-temperature combustion furnace 100 of the present invention improves the combustion efficiency of waste due to preheated combustion air, and the combustion air is supplied while rotating in a spiral shape, thereby increasing the contact path between the waste and air, enabling complete combustion of the waste. do.

When explaining the T-type burner unit 200 of a double structure through FIG. 3, the T-type burner unit 200 of a double structure has an external cylinder 201 through which external air passes and the flame of the high-temperature combustion furnace 100. It includes a passing inner tube 202, and the outer tube 201 and the inner tube 202 have a T-shaped structure having a vertical portion and a horizontal portion as a whole.

The inner tube 202 of the T-type burner unit 200 is formed so that the vertical part and the horizontal part vertically intersect, and one side of the horizontal part is closed and the other side connected to the hot air boiler 300 is open to form a flame discharge pipe 207. do.

The flame of the high-temperature combustion furnace 100 supplied to the inner cylinder 202 of the T-type burner unit 200 is sent to the hot air boiler 300 through the flame discharge pipe 207 disposed horizontally in the T-type burner unit 200. supplied.

The outer cylinder 201 of the T-type burner unit 200 is formed to surround the inner cylinder 202 and forms a closed space between the outer cylinder 201 and the inner cylinder 202 through which external air passes.

A combustion furnace blower 203 and a low-temperature air pipe 206 are disposed on one side of the T-type burner unit 200 to supply cold external air to the outer cylinder 201, so that the external air passes through the closed space and the inner cylinder 202 ) to be preheated by the flame of a high-temperature combustion furnace passing through it.

On the other side of the T-type burner unit 200, a high-temperature air pipe 205 is disposed to supply preheated external air to the combustion chamber 102 of the high-temperature combustion furnace 100, and the preheated air is used as combustion air in the combustion chamber 102. supplied by

The combustion furnace blower 203 can control the supply amount of external air through a separate control unit using a temperature sensor that detects the temperature of the combustion chamber 102.

In the present invention, the installation direction of the T-type burner unit 200 can be adjusted to suit the plan shape or layout of the indoor space, and the high-temperature combustion furnace 100 and hot air boiler 300 can be installed so that the planar installation space is minimized. You can.

In addition, since the T-type burner unit 200 horizontally connects the high-temperature combustion furnace 100 and the hot air boiler 300, the overall installation height of the waste fuel boiler system can be minimized, and the vertical installation space can also be minimized.

When explaining the steam generator 400 through FIG. 3, the steam generator 400 is installed on the outer peripheral surface of the flame discharge pipe 207 of the T-type burner unit 200 and supplies high temperature steam to the high temperature combustion furnace 100.

Specifically, the steam generator 400 has a steam water inlet 401 through which steam is injected, a spiral steam pipe 402 surrounding the outer peripheral surface of the flame discharge pipe 207, and a steam generator that supplies high-temperature steam to the high-temperature combustion furnace 100. Includes a supply pipe (403).

The steam supply pipe 403 is sprayed in the form of mist by the nozzle 402 into the combustion chamber 102 of the high-temperature combustion furnace 100 to control the combustion temperature of the waste, that is, the flame temperature, thereby eliminating harmful nitrogen oxides generated during combustion ( The amount of NOx) can be significantly reduced.

In addition, when high-temperature steam is vaporized and decomposed by a high-temperature flame, hydrogen and oxygen gas are generated, and even polymer compounds that emit toxic components such as RPF can be completely decomposed and burned in an odorless and smokeless state. It can significantly reduce the amount of dust, carbon monoxide, and incompletely combusted hydrocarbons generated, and enables complete combustion while consuming less fuel.

Additionally, in the present invention, the amount of steam supplied can be adjusted according to the temperature of the combustion chamber 102 of the high-temperature combustion furnace 100 or the hot air temperature of the hot air boiler 300.

In the present invention, the supply amount of waste from the waste supply means 10 is adjusted according to the temperature of the combustion chamber 102 of the high temperature combustion furnace 100 or the hot air temperature of the hot air boiler, or the supply amount of external air is adjusted by the combustion furnace blower 203. Or adjusting the supply of steam is performed by a separate control unit that controls the horizontal waste fuel boiler system.

Next, the hot air boiler 300 will be described with reference to FIG. 4.

The hot air boiler 300 is horizontally connected to the T-type burner unit 200,

A heat exchanger (310) in which a heat exchange center pipe (311) is disposed inside a cylindrical body and a plurality of heat exchange pipes (312) are disposed at equal intervals on the outer periphery of the heat exchange center pipe (311) and communicate with the heat exchange center pipe (311),

A blower (320) for the boiler that supplies external air,

A cold air supply pipe 321 disposed on one side of the heat exchanger 310 and supplying external air supplied by the boiler blower 320 to the space between the body of the hot air boiler 300 and the heat exchange pipe 312,

It includes a hot air supply pipe 340 disposed on the other side of the heat exchanger 310 to supply external air heated by the heat exchanger 310 to a user.

The heat exchanger 310 has a flame outlet 410 of the T-type burner unit 200 disposed inside the heat exchange center pipe 311, so that high-temperature flame is introduced into the heat exchanger 310, and a boiler blower ( The external air supplied by 320) is heated while convecting between the heat exchange center pipe 311 and the plurality of heat exchange pipes 312 and is supplied to the consumer through the hot air supply pipe 340.

At this time, the temperature of the hot air is detected by a temperature sensor attached to the hot air supply pipe 340 through a separate control unit that controls the horizontal waste fuel boiler system, and the intensity of the blower for the boiler 320 or the blower for the combustion furnace is adjusted to achieve the desired hot air temperature. The intensity or amount of steam supplied can be automatically adjusted.

Next, the ash discharge cyclone 500 will be described with reference to FIG. 5.

The horizontal waste fuel boiler system of the present invention is equipped with a small ash discharge cyclone 500 that is simply attached to the external side wall of the high-temperature combustion furnace 100, and automatically removes the ash from the waste burned in the high-temperature combustion furnace 100. can be discharged.

The present invention is a cyclone 500 attached to the outer wall of the high-temperature combustion furnace 100, where the combustion ash rotating along the inner wall of the combustion chamber 102 due to a cyclone or swirling flow generated inside the combustion chamber 102 of the high-temperature combustion furnace 100 is disposed of. ), and the ash discharge cyclone 500 itself can generate a cyclone to centrifuge and discharge the combustion ash, so there is no need for a separate large cyclone-type dust collector to separate and discharge the combustion ash.

The ash discharge cyclone 500 of the present invention includes a swirl flow inducing portion 510, a cyclone forming portion 520 disposed below the swirling flow inducing portion 510, and an ash falling portion disposed below the cyclone forming portion 520 ( 530) and an ash collection unit 540 disposed below the ash dropping unit 530.

The swirl flow inducing portion 510 of the present invention includes an upper swirl flow inducing outer cylinder 511 provided with a connection pipe 515 connected to the high temperature combustion furnace 100, a lower swirling flow inducing outer cylinder 513, and the upper/lower swirl flow inducing outer cylinder 513. It includes a swirling flow-inducing inner cylinder 512 installed to penetrate the inner space of the lower swirling flow-inducing outer cylinders 511 and 513 upward and downward.

A closed space is formed between the upper/lower swirl flow inducing outer cylinders 511, 513 and the swirling flow inducing inner cylinder 512 so that the combustion ash discharged from the high-temperature combustion furnace 100 can circulate, and the upper/lower swirling flow inducing outer cylinder Swirl flow wings 514 that promote swirl flow formation may be additionally formed on the inner circumferential wall of (511, 513) or the outer circumferential wall of the swirl flow inducing inner tube 512.

The swirl flow inducing inner cylinder 512 is installed to penetrate the inner space of the upper and lower swirl flow inducing outer cylinders 511 and 513, and a swirl flow rising hole 516 is formed at the lower end, and a discharge hole (516) is formed at the upper end. 517) is formed to discharge fine combustion ash that swirls upward in the cyclone forming portion 520.

The cyclone forming portion 520 is formed with a cylindrical inner space, and an inclined plate 521 whose inner diameter narrows downward is disposed in the inner space to promote the formation of a swirling flow.

Due to the cyclone forming part 520 of this structure, the combustion material flowing into the inner space of the cyclone forming part 520 is rotated by the swirling flow, and the light combustion material among the combustion material is collected at the center of the swirling flow leading part ( It rises through the swirling flow rising hole 516 of the swirling flow induction part 510 and is discharged to the discharge hole 517 of the swirling flow inducing part 510, and the heavy combustion ash among the combustion ash is collected and accumulated on the lower side of the cyclone forming part 520.

An elastic falling device 550 for discharging combustion ash is formed on the lower side of the cyclone forming part 520, and when the heavy combusting ash accumulated on the lower side of the cyclone forming part 520 collects more than a certain weight, an ash falling part disposed at the bottom ( 530).

An ash collection part 540 is formed at the lower part of the ash falling part 530, and an ash discharge stopper 541 is provided at the lower part of the ash collecting part 540. A separate observation window is provided to visually observe the loading amount of materials.

Next, the elastic drop device 550 for discharging combustion ashes of the present invention will be described in detail.

The elastic drop device 550 of the present invention includes a rotatable support plate 551, one end of which is rotatably installed on the bottom plate 522 of the cyclone forming portion 520 to load combustion material;

a support bar 552, one end of which is rotatably connected to the pivotable support plate 551 and the other end rotatably installed on the inner wall of the ash falling portion 531 to support the pivotable support plate 551;

One end is connected to one side of the support bar 552, and the other end is fixed to the inner wall surface 531 of the ash drop portion and includes an elastic spring 553 that elastically supports the support bar 552.

When explaining the operation process of the elastic drop device 550 of the present invention, initially, the elastic spring 553 pulls the support bar 552 to prevent the rotation support plate 551 from rotating, and then the rotation support plate 551 is When combustion ashes of a certain weight or more gather to overcome the tensile force of the elastic spring 553, the support bar 552 rotates and rotates the pivoting support plate 551 to move the combustion ashes loaded on the pivoting support plate 551 to the falling portion 530. It is dropped to .

At this time, the amount of heavy combustion material loaded on the rotating support plate 551 increases as incomplete combustion occurs, so the frequency or number of times that the rotating support plate 551 rotates and drops the combustion material increases as incomplete combustion occurs.

Using this principle, the present invention can determine whether or not the waste is incompletely burned or the degree of incomplete combustion by determining the number or frequency of rotation of the rotating support plate 551 during a certain period of time.

Specifically, a rotation detection sensor that detects the rotation angle or rotation is installed on either the hinge part of the rotation support plate 551 or the hinge parts at both ends of the support bar 552, or the rotation support plate 551 or the support bar 552 is installed. Install a contact or non-contact detection sensor that detects rotational movement.

In addition, a separate control unit that controls the horizontal waste fuel boiler system detects and stores the rotation or rotation frequency of the rotation support plate 551 or the support bar 552 for a certain period of time and supplies it to the high-temperature combustion furnace 100. Information on the type of waste and the weight of the waste is also stored.

In addition, the separate control unit contains data on the amount of combustion air supplied and steam supplied for complete combustion of the waste, depending on the type of waste and the weight of the waste, and the rotation frequency of the rotation support plate 551 or the support bar 552 for a certain period of time. Data is identified in advance through experiments or simulations and stored as table or combustion model information.

When explaining how a control unit equipped with this configuration determines whether waste is incompletely combusted, first, the type of waste (e.g., RDF, RPF, wood pellets, etc.) input into the high-temperature combustion furnace 100 and the weight of the waste are sent to the control unit. Enter.

Based on these input data, the control unit controls the combustion furnace blower 203 or the steam supply water pump to supply the required amount of combustion air and steam to the high-temperature combustion furnace.

Afterwards, the control unit measures the rotation frequency of the rotation support plate 551 or the support bar 552 for a certain period of time, for example, 4 hours or 8 hours, and compares the measured rotation frequency with the rotation frequency stored in the table or combustion model information. , if the measured rotation frequency is greater than the stored rotation frequency, it is judged to be incomplete combustion.

In addition, the control unit can determine the degree of incomplete combustion according to the degree to which the measured rotation frequency is greater than the stored rotation frequency, and can adjust and supply the amount of combustion air and steam supply according to the degree of incomplete combustion.

Although the present invention has been described in detail through specific examples, this is for detailed explanation of the present invention, and the present invention is not limited thereto, and may be understood by those skilled in the art within the technical spirit of the present invention. It is clear that it can be modified or improved.

100: high temperature combustion furnace 101: upper flame outlet
102: combustion chamber
200: T-type burner unit 201: External cylinder
202: Inner cylinder 203: Blower for combustion furnace
204: discharge pipe for boiler connection 205: high temperature air pipe
206: low temperature air pipe 207: flame discharge pipe
300: hot air boiler 310: heat exchanger
311: heat exchange center pipe 312: heat exchange pipe
320: Blower for boiler 321: Cold air supply pipe
330: flue 340: warm air supply pipe
400: Steam generator 401: Steam water inlet
402: Steam pipe 403: Steam supply pipe

500: Re-emission cyclone
510: Swirling flow guidance unit
511: Upper swirl flow inducing outer cylinder 512: Swirling flow inducing inner cylinder
513: Lower swirl flow induction tube 514: Swirl flow wing
515: Connector 516: Swirling flow riser
517: discharge hole
520: Cyclone formation 521: Inclined plate
522: Bottom plate
530: Ash falling part 531: Ash falling part wall
540: Ash collection unit 541: Ash discharge plug
550: Elastic falling device 551: Rotating support plate
552: support bar 553: elastic spring

Claims (1)

In the horizontal waste fuel boiler system,
A high-temperature combustion furnace (100) that burns waste fuel;
A T-type burner unit 200 installed on the upper part of the high-temperature combustion furnace 100 to convert the flame rising from the high-temperature combustion furnace 100 into the horizontal direction;
A hot air boiler (300) connected horizontally to the rear of the T-type burner unit (200) to heat external air and supply hot air;
A horizontal waste fuel boiler system comprising: