KR101228422B1 - Equipment with assembled type of combustion chamber - Google Patents

Abstract

PURPOSE: Combustion equipment having an assembly-type combustion furnace is provided to prevent the malfunction of a combustion device by continuously removing clinkers deposited on each component of a combustion furnace during the operation of the combustion furnace. CONSTITUTION: Combustion equipment having an assembly-type combustion furnace comprises multiple assembly units(100), a connection unit(200), and a combustion body part(500). Multiple assembly units are assembled to form the inner wall of a combustion furnace and are coupled or separated by the connection unit. The combustion body part comprises grate(590) and a turntable(580). The combustion body part forms the outer wall of the combustion furnace while enclosing the assembly units and the connection unit.

Description

EQUIPMENT WITH ASSEMBLED TYPE OF COMBUSTION CHAMBER}

Combustion equipment having a prefabricated combustion furnace according to the present invention, a plurality of plates are coupled to each other to form a combustion furnace space in which the solid fuel is burned, the prefabricated combustion furnace that can be used by simply replacing the part partially damaged by the heat of combustion It relates to a combustion plant having a.

In general, incinerators are fueled in a combustion chamber to achieve combustion conditions (3T; Temperature, Turbulence, Time), followed by combustion of the fuel.In the combustion chamber, flame-burning or (removing) the waste or fuel injected is pyrolyzed (carbonized). And reburn (remove) the unburned gaseous material according to the combustion conditions and fuel conditions.

Such incinerators use not only sawdust or wood chips, but also solid fuels compressed into pellets from business or homes as pellets, and they can be used for boilers, cogeneration, etc. by burning these solid fuels to obtain heat. Devices are being developed.

Boilers using solid fuels are widely used due to their low fuel costs and eco-friendly facilities because they do not use diesel / BC oils (expensive fossil fuels), which are greenhouse gas sources. It is spreading to local power generation facilities and cogeneration as well as to boilers for its own use.

However, when the solid fuel is burned as described above, it is merely supplying combustion air to the ignited solid fuel and burning it, thereby limiting the combustion efficiency.

Therefore, it is not only necessary to supply combustion air but also to improve combustion method to supply combustion air more efficiently, and it is necessary to improve the operation rate by increasing the operation rate by improving the structure of the fuel-burning grate. .

In addition, as the solid fuel is combusted, many ashes and foreign substances such as glass powder or soil contained in the solid fuel melt at the high temperature of the combustion furnace, resulting in slag and clinker.

The ash generated in this way is not quickly discharged to the outside and is deposited on each component of the combustion device, which causes a problem of lowering combustion efficiency and causing failure of the combustion device.

In particular, when the inner wall of the furnace and its surroundings are damaged due to the high heat caused by the combustion of the solid fuel, there is a problem in that the inner wall of the furnace or the furnace itself needs to be replaced.

In addition, when the parts of the furnace are partially damaged, as the operation of the furnace is frequently stopped for the replacement, there is a problem in that the production efficiency of energy reuse is drastically lowered, resulting in economic losses.

Patent Document Registration Patent 10-1103000

The present invention has been made to solve the above problems, to provide a combustion facility having a prefabricated combustion furnace that can be operated by partially replacing the inner wall of the furnace when the solid fuel is burned and the inner wall of the furnace is damaged. There is a purpose.

A combustion facility having a prefabricated combustion furnace according to the present invention has an object of providing a combustion facility having a prefabricated combustion furnace that can be easily installed in the inner wall of the furnace to reduce the cost of the furnace installation time.

A combustion facility having a prefabricated combustion furnace according to the present invention has an object to provide a combustion facility having a prefabricated combustion furnace capable of preventing frequent operation of the combustion furnace due to damage to the inner wall of the combustion furnace.

Combustion equipment having a prefabricated combustion furnace according to the present invention is a prefabricated combustion furnace that prevents the failure of the combustion device by continuously removing the clinker deposited on the grate inside the combustion furnace and each component of the furnace during the operation of the combustion furnace. It is an object to provide a combustion facility having.

Combustion equipment having a prefabricated combustion furnace according to the present invention, the assembly is a plurality of assembly to form an inner wall of the combustion furnace to form a combustion furnace that is a combustion space that can produce heat energy as the solid fuel 10 enters into and combusts. Unit 100; A connection unit 200 allowing the assembly units 100 to be coupled or separated from each other; And a grate 590 supporting the solid fuel 10, and a turntable 580 disposed below the grate 590 to have an annular shape, such that the grate 590 is rotated. And a combustion body part 500 forming an outer wall of the combustion furnace while surrounding the unit 100 and the connection unit 200.

The lower portion of the combustion body portion 500, the entrance portion 510 is provided to be opened and closed, the front end is arranged to enter the interior of the combustion body portion 500 through the entry portion 510. The cooling body 300 and the combustion body portion 500 is disposed at the outside of the combustion body portion 500 to cool the portion entered into the combustion body portion 500 through the circulation of water or air. Protrudingly formed on the outer surface of the cooling body portion 300 entered into the inside, and removes the clinker 30 generated in the grate 590, 400 and the combustion body portion 500 Is connected to the cooling body 300 disposed outside of the) is provided with a power transmission unit 370 for transmitting power to rotate the cooling body 300.

The combustion body part 500 is integrally formed on the outer surface of the combustion body part 500, and is divided in the vertical direction to form a plurality of layers while separately dispensing and injecting air in each of the combustion body parts 500. It is connected to the upper portion of the cooling unit 600 and the combustion body 500 for cooling the combustion body portion 500 by sucking the air entered into the combustion body portion 500 by the cooling unit 600 Negative pressure induction unit 700 is formed so that the negative pressure is formed therein.

The assembly unit 100 includes a plurality of assembly plates 110 in the form of a plate assembled with each other, the connection unit 200, the assembly plate 110 is such that the assembly plate (110) to be mutually coupled or separated ( The coupling protrusion 210 formed on the upper portion of the 110, and the coupling groove 220 is formed in the lower portion of the other assembly plate (110 ') is fitted to the coupling protrusion 210.

The assembly plate 110 is a coupling single layer 120 is formed with a single layer on the left and right sides of the assembly plates 110 and 110 ', respectively, so that different assembly plates 110 and 110' overlap each other in a horizontal direction. ) And a coupling flange 130 protruding in a horizontal direction from the bottom of the assembly plates 110 and 110 ′ so that different assembly plates 110 and 110 ′ may be stacked in the vertical direction. The groove 220 is formed at a lower portion of the coupling flange 130 of the building plates 110 and 110 ′.

The connection unit 200, a plurality of nut grooves formed at positions corresponding to each of the edges of the respective assembly plates (110, 110 ') to assist in the removal of the different assembly plates (110, 110') ( 230 and a fastening bolt 240 coupled to or separated from the nut groove 230.

The connecting unit 200 is formed between the different assembly plates (110, 110 '), when the vertical assembly of the different assembly plates (110, 110') are formed between the annular connecting frame for connecting so as to be mutually removable It further comprises 260, the connecting frame 260, the upper connecting piece 262 extending in the upward direction from the connecting frame 260 and the lower portion extending in the downward direction from the connecting frame 260 It includes a connection piece 264, the upper connection piece 262, the nut groove 230 is further provided, the lower connection piece 264, the coupling groove 220 is further provided.

The cooling body portion 300, the rod-shaped internal cooling tube 312 and the inside of the combustion body portion 500 is disposed through the entry position 510, and in the internal cooling tube 312 A cooling housing 310 formed of an external cooling tube 314 having a rod shape which is formed while being extended to the outside of the combustion body part 500; Is formed extending outward from the external cooling pipe 314, partitioning the cooling material made of water or air entering from the outside for cooling and the cooling material discharged to the outside after being circulated in the cooling housing 310 Cooling compartment tank 320; A joint 330 for interconnecting the cooling housing 310 and the cooling compartment 320 to maintain the fixed state of the cooling compartment 320 when the cooling housing 310 is rotated; Supply drain pipe 340 is connected to the outer surface of the cooling compartment 320 is composed of an entry pipe 342 into which the cooling material enters and a discharge pipe 344 through which the cooling material circulated in the cooling housing 310 is discharged. ; And the cooling material connected to the entry pipe 342 and connected to the inside of the cooling compartment 320 and the inside of the cooling housing 310 to be injected through the entry pipe 342 to the cooling housing ( It includes; a cooling supply pipe 350 to be supplied inside.

The combustion body part 500 is arranged to penetrate the grate 590 upwardly from the lower part of the turntable 580 to supply the solid fuel 10 to the inside of the combustion body part 500 from the outside. A hopper 585 is included.

Outside the combustion body 500, the conveyor 535 for the solid fuel 10 is transferred, and the solid fuel 10 transferred from the conveyor 535 flows into the hopper 585. The cylinder-type cylinder portion 520 to be entered into, and pushes the solid fuel 10 introduced into the cylinder portion 520 while reciprocating while entering the inside from the outside of the cylinder portion 520 A cylinder rod part 530 to be transported is included.

The cooling unit 600, an air inlet 610 for injecting air into the combustion body 500 from the outside, and a flow sensor for measuring the pressure of the air supplied into the cooling unit 600 ( 603 and an air conditioner 605 for adjusting the amount of air supplied to the cooling unit 600 according to the pressure of the air measured by the flow sensor 603.

The combustion body part 500 includes a starter burner 570 which provides a flame in the combustion body part 500 so that the solid fuel 10 may be ignited, and thermal energy generated by the combustion furnace 500. It includes an energy exchange unit 575 to convert to steam or electricity.

Combustion equipment having a prefabricated combustion furnace according to the present invention, since the internal wall of the combustion furnace can be easily replaced partially when the inner wall of the furnace is damaged, there is an economic effect that can improve the efficiency of the operation and reduce the replacement cost.

Combustion equipment having a prefabricated combustion furnace according to the present invention, there is an economic effect because it can reduce the cost while reducing the furnace installation time.

Combustion equipment having a prefabricated combustion furnace according to the present invention can increase the operating efficiency of the combustion furnace by preventing the failure of the combustion device by continuously removing the clinker deposited on each component of the furnace during the operation of the combustion furnace. It is effective for improving productivity.

1 is a view showing a combustion facility having a prefabricated combustion furnace according to the present invention.
Figure 2a is a view showing an embodiment of a combustion facility having a prefabricated combustion furnace according to the present invention.
2b is a view showing an embodiment of a combustion facility according to FIG. 2a.
Figure 3a is a view showing another embodiment of a combustion facility having a prefabricated combustion furnace according to the present invention.
3B is a view showing an embodiment of a combustion facility according to FIG. 3A.
Figure 4a is a view showing another embodiment of a combustion facility having a prefabricated combustion furnace according to the present invention.
4B is a view showing an embodiment of a combustion facility according to FIG. 4A.
Figure 5a is a view showing another embodiment of a combustion facility having a prefabricated combustion furnace according to the present invention.
FIG. 5B is a view showing an embodiment of a combustion facility according to FIG. 5A.
6a, 6b, and 6c are views showing another embodiment of the prefabricated combustion furnace according to the present invention.
7 is a view showing a main portion of a combustion facility having a prefabricated combustion furnace according to the present invention.
8 is a view showing a combustion facility having a prefabricated combustion furnace according to FIG.
9 is a view showing a state of use of the combustion equipment having a prefabricated combustion furnace according to the present invention.

DETAILED DESCRIPTION The following detailed description of the invention refers to the accompanying drawings that show, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, certain features, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with one embodiment. It is also to be understood that the position or arrangement of the individual components within each disclosed embodiment may be varied without departing from the spirit and scope of the invention. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is to be limited only by the appended claims, along with the full scope of equivalents to which such claims are entitled, if properly explained. In the drawings, like reference numerals refer to the same or similar functions throughout the several views, and length and area, thickness, and the like may be exaggerated for convenience.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, so that those skilled in the art can easily carry out the present invention.

In the following detailed description, as an example, a plurality of plates are mutually coupled to form a combustion furnace space in which solid fuel is combusted, and a combustion facility having a prefabricated combustion furnace that can be used by simply replacing parts partially damaged by combustion heat [ In particular, it will be said that the technical configuration of the assembly unit, the connection unit] can be equally applied.

1 is a view showing a combustion facility having a prefabricated combustion furnace according to the present invention.

Referring to Figure 1 is a combustion facility having a prefabricated combustion furnace according to the present invention, a plurality of pieces are assembled together to form a combustion furnace that is a combustion space capable of producing thermal energy as the solid fuel 10 enters into and combusts. It has an assembly unit 100 forming an inner wall.

Then, the assembly unit 100 has a connection unit 200 to be coupled to or separated from each other.

In addition, the grate 590 for supporting the solid fuel 10, and disposed below the grate 590 and has an annular shape, and includes a turntable 580 for rotating the grate 590, It has a combustion body 500 that forms the outer wall of the combustion furnace while surrounding the assembly unit 100 and the connection unit 200.

Here, the assembly unit 100, the assembly plate 110 of a plurality of plates are assembled to each other.

In addition, the connection unit 200, the coupling protrusion 210 formed on the upper portion of the assembly plate 110 and the other assembly plate 110 'so that the assembly plate 110 can be mutually coupled or separated. It is formed in the coupling protrusion 210 includes a coupling groove 220 is fitted.

The assembly plate 110 is a coupling single layer 120 is formed with a single layer on the left and right sides of the assembly plates 110 and 110 ', respectively, so that different assembly plates 110 and 110' overlap each other in a horizontal direction. Has

Further, the assembly plates 110 and 110 'further include a coupling flange 130 protruding in the horizontal direction, respectively, on the upper and lower portions of the assembly plates 110 and 110' to be laminated in the vertical direction. .

The coupling flange 130 may be omitted, depending on the position of the assembly plate 110.

In addition, the connection unit 200, a plurality of nuts formed at positions corresponding to each other the edge of each assembly plate (110, 110 ') to assist the removal of the different assembly plate (110, 110') mutually A groove 230 and a fastening bolt 240 coupled to or separated from the nut groove 230 are further included.

As a result, the assembly unit 100, the plurality of the assembly plate (110, 110 ') is connected to the horizontal and vertical direction through the connecting unit 200 to form the inner wall of the combustion furnace.

The shape of the assembly plates 110 and 110 ′ is basically formed in a plate shape having a curved shape, and may be partially different in shape by forming other components.

Likewise, the coupling protrusion 210 of the connection unit 200 may also be formed in various forms if the assembly plates 110 and 110 'may be firmly connected to each other, and the shape of the coupling protrusion 210 may be such that Accordingly, the coupling groove 220 has a corresponding shape to be coupled to the coupling protrusion 210.

The assembly unit 100 and the connection unit 200 may be made of various materials such as iron or metal having high heat resistance.

Figure 2a is a view showing an embodiment of a combustion facility having a prefabricated combustion furnace according to the present invention.

2b is a view showing an embodiment of a combustion facility according to FIG. 2a.

As mentioned above, the assembling unit 100 includes an assembling plate 110 in the form of a plate, a plurality of which are assembled together.

In addition, the connection unit 200, the coupling protrusion 210 formed on the upper portion of the assembly plate 110 and the other assembly plate 110 'so that the assembly plate 110 can be mutually coupled or separated. It is formed in the coupling protrusion 210 includes a coupling groove 220 is fitted.

The assembly plate 110 is a coupling single layer 120 is formed with a single layer on the left and right sides of the assembly plates 110 and 110 ', respectively, so that different assembly plates 110 and 110' overlap each other in a horizontal direction. Has

2A and 2B show that different assembling plates 110 and 110 'are assembled in the horizontal direction.

To this end, on both sides of the assembly plate 110, a coupling single layer 120 is formed so that the other assembly plate 110 'can be overlapped.

The coupling single layer 120 is preferably formed such that the thickness of the building plate 110 and the other building plate 110 'overlapping each other is not greater than the thickness of the building plates 110 and 110'.

At this time, the coupling single layer 120 formed on both sides of the assembly plate 110, one side is intaglio formed on the inner surface and the other side is formed staggered mutually.

This, the bonding monolayer 120 intaglio formed on the inner surface of the assembly plate 110 is in close contact with the bonding monolayer 120 'formed intaglio on the outer surface of the other assembly plate 110, the combined thickness of the assembly This is to be formed so as not to be thicker than the thickness of the plate (110, 110 ').

Here, the nut grooves 230 and 230 'are formed in the coupling single layers 120 and 120', respectively.

Since the nut grooves 230 and 230 'formed in the coupling monolayers 120 and 120' are formed at mutually corresponding positions, the nut grooves 120 and 120 'are overlapped with each other. 230 and 230 ′ are formed to penetrate through the bonding monolayers 120 and 120 ′.

The coupling single layer (120, 120 '), it is possible to be firmly coupled to each other by a fastening bolt 240 is coupled to or separated from the nut groove (230, 230').

Similarly, when separating the two assembly plates (110, 110 '), it can be easily separated by separating the fastening bolt 240 in the nut groove (230, 230').

In this way, the plurality of building plates 110, 110 'are assembled together in a horizontal direction so that the flat cross section has a circular or polygonal shape.

Particularly, after the plurality of building plates 110 and 110 'are assembled together to form a single layer having a flat cross section or a polygonal cross section, the other building plates 110 and 110' may be disposed thereon. ) Can be assembled in the vertical direction.

Vertical assembly of the plurality of assembly plates 110 and 110 ′ will be described in detail with reference to FIG. 3.

Figure 3a is a view showing another embodiment of a combustion facility having a prefabricated combustion furnace according to the present invention.

3B is a view showing an embodiment of a combustion facility according to FIG. 3A.

3A and 3B show that different assembly plates 110 and 110 'are assembled in the vertical direction.

Referring to FIGS. 2A and 2B, referring to FIGS. 3A and 3B, as mentioned above, the connection unit 200 includes the assembly plate 110 such that the assembly plates 110 are mutually coupled or separated. It has a coupling protrusion 210 formed on the top.

In addition, the connection unit 200 is formed at the lower portion of the other assembly plate 110 'includes a coupling groove 220 to which the coupling protrusion 210 is fitted.

The assembly plate 110 is a coupling single layer 120 is formed with a single layer on the left and right sides of the assembly plates 110 and 110 ', respectively, so that different assembly plates 110 and 110' overlap each other in a horizontal direction. Has

The coupling protrusion 210 formed on the assembly plate 110 and the coupling groove 220 formed of another assembly plate 110 'are different from the assembly plate 110 and the assembly plate 110'. ) Can be combined with each other in the vertical direction.

In addition, the coupling single layer 120 performs a function of allowing different assembly plates 110 and 110 'to be assembled in a horizontal direction.

Here, the coupling protrusion 210 is connected to the coupling head 212 and the coupling head 212 and the assembly plate 110 to enter the coupling groove 220, but the coupling head 212 of It is composed of a pin 214 having a circumference smaller than the circumference.

In addition, the coupling groove 220, the head groove 222 into which the coupling head 212 enters, and the coupling projection 210 enters the coupling groove 220 and then flows in the horizontal direction, the mounting It is composed of a pin groove 224 having a groove of a shape corresponding to the circumference of the pin 214.

That is, the coupling groove 220 is formed so that the size of the groove is changed toward the horizontal direction.

Looking at the process of the coupling protrusion 210 is connected to the coupling groove 220, the coupling head 212 formed on the assembly plate 110 is the head groove 222 of the other assembly plate 110 ' After passing through), the mounting pin 214 of the mounting plate 110 is placed in the pin groove 224 of the other mounting plate 110 'while flowing in the horizontal direction.

As a result, the assembly plate 110 and the other assembly plate 110 ′ may be laminated in the vertical direction.

At this time, the coupling flange 130 formed on the lower portion of the assembly plate 110, while being mounted on the upper portion of the other assembly plate 110 'vertically coupled to the lower portion of the assembly plate 110, the two assembly plates ( 110 and 110 ') can be stably coupled to each other.

In this manner, a plurality of different assembly plates 110 and 110 'may be coupled in the vertical direction to the top or the bottom of the assembly plates 110 and 110'.

Similarly, when the assembly plates 110 and 110 'are separated from each other, the assembly plate 110' coupled to the lower portion of the assembly plate 110 is moved in a horizontal direction to be mounted on the pin groove 224. The mounting pin 214 is moved to a position where the head groove 222 is formed.

In addition, the coupling head 212 is separated from the head groove 222 through the head groove 222, so that the assembly plates 110 and 110 'are separated from each other.

At this time, the vertical coupling method of the two assembly plates (110, 110 ') is only one embodiment, if it can be firmly coupled to each other the connection unit 200 may be formed in various forms.

In this way, by being closely bonded to each other by the coupling single layer (120, 120 ') of the building plate (110, 110'), the building plate (110, 110 ') can be coupled or separated in a horizontal direction to each other, Through the coupling protrusions 210 and the coupling grooves 220 of the connection unit 200 formed on the assembly plates 110 and 110 ', the assembly plates 110 and 110' may be coupled to or separated from each other in the vertical direction. Can be.

Here, the connection unit 200, the plurality of assembly plates 110, 110 'different from each other to assist the removal of the mutually formed assembly plate 110, 110' A nut groove 230 and a fastening bolt 240 coupled to or separated from the nut groove 230 may be further included.

The nut grooves 230 formed on each of the assembling plates 110 and 110 ′ are disposed on the same horizontal line, and then the fastening bolts 240 are coupled to each other while simultaneously passing through the nut grooves 230. In this case, the assembly plates 110 and 110 ′ may be more firmly coupled to each other.

Figure 4a is a view showing another embodiment of a combustion facility having a prefabricated combustion furnace according to the present invention.

4B is a view showing an embodiment of a combustion facility according to FIG. 4A.

Referring to FIGS. 2A and 3B, FIG. 4A illustrates the configuration of the building plates 110 and 110 ′ according to other components.

As mentioned above, the assembly plate 110 is a single layer on the left and right sides of the assembly plates 110 and 110 ', respectively, so that different assembly plates 110 and 110' overlap each other in a horizontal direction. It has a bonding monolayer 120 is formed.

In this case, the coupling single layer 120 may be formed on only one of both sides according to the position of the assembly plate 110.

In addition, the connection unit 200 has a coupling protrusion 210 formed on the assembly plate 110 so that the assembly plates 110 are mutually coupled or separated.

In addition, the connection unit 200 is formed in the lower portion of the other assembly plate 110 'includes a coupling groove 220 to which the coupling protrusion 210 is fitted.

Here, the coupling protrusion 210 is connected to the coupling head 212 and the coupling head 212 and the assembly plate 110 to enter the coupling groove 220, but the coupling head 212 of It is composed of a pin 214 having a circumference smaller than the circumference.

In addition, the coupling groove 220, the head groove 222 into which the coupling head 212 enters, and the coupling projection 210 enters the coupling groove 220 and then flows in the horizontal direction, the mounting It is composed of a pin groove 224 having a groove of a shape corresponding to the circumference of the pin 214.

For example, as air is injected from the outside to the inside of the assembly plate 110, a cooling guide piece 150 may be formed to guide the outside air to enter the inside.

When the cooling guide piece 150 is formed on the assembly plate 110, the cooling guide groove is formed in the assembly plate 110 at the position where the assembly plate 110 is formed in the cooling guide piece 150. 116 is formed.

That is, the cooling flow groove 116, the cooling air from the outside of the assembly plate 110 is to perform a function to enter into the interior of the assembly plate 110.

As mentioned above, the assembly plate 110 and the other assembly plate 110 ′ may be coupled in a horizontal direction while overlapping each other through the coupling single layer 120.

In addition, the coupling protrusion 210 formed on the assembly plate 110 and the coupling groove 220 formed of another assembly plate 110 ′ are different from the assembly plate 110 and the assembly plate 110 ′. ) Can be combined in a vertical direction.

At this time, by the formation of the cooling guide piece 150, the position and the arrangement in which the coupling groove 220 is formed can be changed, the position of the coupling groove 220 at the position where the coupling protrusion 210 is formed. It is formed to correspond.

Similarly, after the nut grooves 230 formed on each of the assembling plates 110 and 110 ′ are disposed on the same horizontal line, the fastening bolts 240 pass through the nut grooves 230 simultaneously. In this case, the assembly plates 110 and 110 ′ may be more firmly coupled to each other.

Figure 5a is a view showing another embodiment of a combustion facility having a prefabricated combustion furnace according to the present invention.

FIG. 5B is a view showing an embodiment of a combustion facility according to FIG. 5A.

2A to 3B, in FIG. 5, different assembling plates 110 and 110 ′ are assembled to face each other.

Such a case may be formed at, for example, a door portion openable to a combustion furnace.

As mentioned above, the connection unit 200 has a coupling protrusion 210 formed on the front surface of the assembly plate 110 so that the assembly plate 110 can be mutually coupled or separated.

In addition, the connection unit 200 is formed at a position corresponding to the coupling protrusion 210 on the front of the other assembly plate 110 'includes a protrusion coupling groove 250 to which the coupling protrusion 210 is fitted. do.

The assembly plate 110 is a coupling single layer 120 is formed with a single layer on the left and right sides of the assembly plates 110 and 110 ', respectively, so that different assembly plates 110 and 110' overlap each other in a horizontal direction. Has

The assembly protrusion 110 formed on the assembly plate 110 and the protrusion coupling groove 250 formed of another assembly plate 110 ′ are different from the assembly plate 110 and the assembly plate 110. ') Can be combined in the vertical direction.

In addition, the coupling single layer 120 performs a function of allowing different assembly plates 110 and 110 'to be assembled in a horizontal direction.

Here, the coupling protrusion 210, the coupling head 212 entering the protrusion coupling groove 250 is formed in a shape corresponding to the protrusion coupling groove 250, the coupling protrusion 210 is protruding The coupling groove 250 is to be coupled in a form fitted.

As such, the mutual coupling of the assembly plate 110 and the other assembly plate 110 ′ may be formed in various forms as long as they can be firmly coupled to each other or easily separated from each other.

Here, after the nut grooves 230 formed on each of the assembling plates 110 and 110 ′ are disposed on the same horizontal line, the fastening bolt 240 penetrates the nut grooves 230 simultaneously. Being coupled, the building plate (110, 110 '), can be more firmly coupled to each other.

6a, 6b, and 6c are views showing another embodiment of the prefabricated combustion furnace according to the present invention.

Referring to FIGS. 2A to 3B, referring to FIGS. 6A, 6B and 6C, as mentioned above, in the assembly plate 110, different assembly plates 110 and 110 ′ overlap each other in a horizontal direction. It has a coupling monolayer 120 is formed with a single layer on each of the left and right sides of the building plate (110, 110 ') to be assembled.

In addition, the connection unit 200 is formed in the lower portion of the other assembly plate 110 'includes a coupling groove 220 to which the coupling protrusion 210 is fitted.

Here, the coupling protrusion 210 is connected to the coupling head 212 and the coupling head 212 and the assembly plate 110 to enter the coupling groove 220, but the coupling head 212 of It is composed of a pin 214 having a circumference smaller than the circumference.

In addition, the coupling groove 220, the head groove 222 into which the coupling head 212 enters, and the coupling projection 210 enters the coupling groove 220 and then flows in the horizontal direction, the mounting It is composed of a pin groove 224 having a groove of a shape corresponding to the circumference of the pin 214.

In addition, the connection unit 200, a plurality of nuts formed at positions corresponding to each other the edge of each assembly plate (110, 110 ') to assist the removal of the different assembly plate (110, 110') mutually A groove 230 and a fastening bolt 240 coupled to or separated from the nut groove 230 are further included.

In particular, the connection unit 200, when the vertical assembly of the different assembly plates (110, 110 '), formed between the different assembly plates (110, 110') of the annular connecting to be detachable from each other It further includes a connecting frame 260.

As a result, the connecting frame 260 is not connected directly to each other, when the different assembly plates 110 and 110 'are vertically connected, the connecting frame 260 Through this function to be able to be connected vertically.

The assembly plates 110 and 110 ′ different from each other through the connecting frame 260 may be disposed on the same vertical line, not on the vertical lines that are shifted from each other.

To this end, the connecting frame 260, the upper connecting piece 262 extending in the upward direction from the connecting frame 260, and the lower connecting piece 264 extending in the downward direction from the connecting frame 260 Include.

The upper connection piece 262 is further provided with the nut groove 230 formed at the edges of the assembly plates 110 and 110 ′, and the lower connection piece 264 has a lower portion of the assembly plate 110. Is formed in the coupling groove 220 is further provided to allow the coupling protrusion 210 of the other assembly plate 110 'is fitted.

Here, the nut groove 230 used when the assembling plates 110 and 110 ′ are directly and vertically connected to each other is formed in the upper connecting piece 262 so as to correspond to the upper connecting piece 262.

In addition, the coupling groove 220 used when the assembling plates 110 and 110 ′ are directly connected to each other vertically is omitted from the assembling plate 110 and formed on the lower connection piece 264 to replace the function thereof. Done.

As shown in FIG. 6A, the connection frame 260 includes an upper connection piece 262 extending upwardly from the connection frame 260 and a lower connection piece extending downwardly from the connection frame 260. 264 may be formed so that each assembly plate 110 and 110 ′ may be vertically connected to each other.

Subsequently, it is natural that the other assembly plates 110 are connected side by side in the horizontal direction on both sides of the assembly plates 110 and 110 ′ respectively disposed on the upper connection piece 262 and the lower connection piece 264. .

As shown in FIG. 6B, when the connecting frame 260 is the lowermost layer of the combustion furnace, the lower connecting piece 264 is omitted from the connecting frame 260, and a plurality of assembly plates 110 are disposed on the upper connecting piece 262. , 110 ').

At this time, the side of the assembly plate (110, 110 ') disposed on the upper connection piece 262, the other assembly plate 110 is connected side by side in the horizontal direction, of the assembly plate (110, 110') It is obvious that another assembly plate 110, 110 ′ or another connecting frame 260 may be connected to the upper portion.

As shown in FIG. 6C, when the connecting frame 260 is the uppermost layer of the combustion furnace, the upper connecting piece 262 is omitted from the connecting frame 260, and a plurality of assembly plates 110 are disposed on the lower connecting piece 264. , 110 ').

Similarly, the other building plate 110 is connected side by side in the horizontal direction on both sides of the building plate (110, 110 ') disposed on the lower connection piece 264, the of the building plate (110, 110') It is obvious that another assembly plate 110, 110 ′ or another connecting frame 260 may be connected to the lower portion.

7 is a view showing a main portion of a combustion facility having a prefabricated combustion furnace according to the present invention.

8 is a view showing a combustion facility having a prefabricated combustion furnace according to FIG.

Referring to Figures 7 and 8, the cooling body portion 300, the internal cooling tube 312 of the rod-shaped that is arranged to enter the interior of the combustion body portion 500 through the entry position 510, It extends from the inner cooling tube 312 has a cooling housing 310 consisting of a rod-shaped outer cooling tube 314 disposed on the outside of the combustion body portion 500.

Is formed extending outward from the external cooling pipe 314, partitioning the cooling material made of water or air entering from the outside for cooling and the cooling material discharged to the outside after being circulated in the cooling housing 310 It has a cooling compartment 320.

While the cooling housing 310 and the cooling compartment tank 320 are interconnected, a joint 330 is formed to maintain the fixed state of the cooling compartment 320 when the cooling housing 310 is rotated. do.

Supply drain pipe 340 is connected to the outer surface of the cooling compartment 320 is composed of an entry pipe 342 into which the cooling material enters and a discharge pipe 344 through which the cooling material circulated in the cooling housing 310 is discharged. Is formed.

 The cooling material 310 connected to the entry pipe 342 and disposed to be connected to the inside of the cooling compartment 320 and the inside of the cooling housing 310 to be injected through the entry pipe 342 is the cooling housing 310. Cooling supply pipe 350 to be supplied to the inside is formed.

And, the combustion body portion 500, while placing the grate 590 upward in the lower portion of the turntable 580, the solid fuel 10 from the outside into the interior of the combustion body portion 500 And a hopper 585 for feeding.

The lower portion of the combustion body portion 500, the access mounting portion 510 is formed to be opened and closed.

The entrance portion 510 is provided with a first sealing bearing 512 surrounding the outer surface of the portion where the internal cooling tube 312 and the external cooling tube 314 are connected, and the combustion body portion 500 of It has a first sealed door 514 that isolates the inside and the outside.

In addition, the entry mounting portion 510 is provided with a second sealing bearing 516 surrounding the outer surface of the internal cooling pipe 312 entered into the first sealing door 514, the first sealing In addition to the door 514 includes a second sealed door 518 to double-insulate the inside and the outside of the combustion body portion 500.

The first sealed door 514 is injected with air from the outside of the first sealed door 514 to the space between the first sealed door 514 and the second sealed door 518 to provide a space therebetween. A cooling inlet 515 is formed to allow cooling.

The cooling air injected into the cooling inlet 515 directly cools the space between the first sealing door 514 and the second sealing door 518 to form a peripheral component of the combustion body 500. To protect them.

As a result, the entry portion 510 forms a dual structure of the first sealing door 514 and the second sealing door 518, and from the outside of the combustion body 500 to the inside of the cooling unit. Body portion 300 is to be operated to be operated smoothly entering and connected.

And, the front end is placed into the combustion body portion 500 through the entry position 510 and the end is disposed outside the combustion body portion 500 to enter the combustion body portion 500. Cooling body 300 is formed to cool the portion through the circulation of water or air.

Protruding to the outer surface of the cooling body portion 300 entered into the combustion body portion 500, the clinker removal portion 400 for removing the clinker 30 generated in the grate 590 is formed do.

In addition, a power transmission unit 370 is connected to the cooling body 300 disposed outside the combustion body 500 to transmit power to rotate the cooling body 300.

The lower portion of the combustion body 500 having a space where the solid fuel 10 is burned is provided with a grate 590 in which the solid fuel 10 is burned.

In the process of burning the solid fuel 10 in the grate 590, the foreign matter in the solid fuel 10 is ignited, the clinker 30 is fused on the grate 590 is generated.

In this case, when the clincher 30 is not removed, the combustion efficiency of the solid fuel 10 is lowered and other structures including the grate 590 are damaged.

For this reason, the clinker 30 needs to be repeatedly removed. For this purpose, the clinker removal unit 400 is used.

The clinker removal unit 400 has a plurality of removal blades 410 for removing the clinker 30 while directly rubbing against the clinker 30 generated in the grate 590.

Here, the side of the removal blade 410 has a triangular shape.

The shape of the removal blade 410 is only an embodiment, it is natural that various sizes and shapes are used according to the needs of the user.

At this time, since the inside of the combustion body portion 500 maintains a state in which high heat of about 900 to 1500 ° C. is generated by the combustion of the solid fuel 10, the cleanser agent including the removal blade 410. Rejection 400 is a heat-resistant metal is to be used.

In addition, the plurality of removal blades 410 are rotated to remove the clinker 30 while rubbing against the clinker 30.

The removal blade 410 is rotated while being spaced apart from the grate 590 so that the removal blade 410 is rotated while being supported to remove the clinker 30 on the grate 590. Cooling body portion 300 is used.

At this time, the cooling body 300, while supporting the clinker removal unit 400 and to rotate at the same time, performs the function of cooling the clinker removal unit 400.

To this end, the cooling body 300, the rod-shaped inner cooling tube 312 and the internal shape of the rod is disposed in the combustion body 500, and extending from the inner cooling tube 312 while the combustion body It has a cooling housing 310 composed of a rod-shaped external cooling tube 314 disposed outside the portion 500.

In particular, the cooling body portion 300 is disposed while being connected to the inside from the outside of the combustion body portion 500, a plurality of can be arranged according to the needs of the user.

In the present invention, the cooling body portion 300 may be provided with a pair facing each other while being connected to the inside from the outside of the combustion body portion 500.

In addition, the lower portion of the combustion body 500, the entry mounting portion 510 is formed so that the internal cooling tube 312 can enter the interior of the combustion body 500.

That is, the cooling body 300, the front end is disposed through the entry position 510 into the combustion body portion 500 and the end is disposed outside the combustion body portion 500 is the The part entered into the combustion body 500 is cooled by circulation of water or air.

As such, the outer surface of the cooling body part 300 that enters into the combustion body part 500 protrudes from the clinker removal part 400, so that the clinker removal part 400 is the cooling body part 300. The rotation is linked to the rotation of the will be to remove the clinker 30 generated in the grate 590.

The power transmission unit 370 transmits power to the external cooling tube 314 of the cooling body part 300 disposed outside the combustion body part 500 so that the cooling body part 300 is rotated. Is formed.

The power transmission unit 370 is connected to the external cooling tube 314 while being provided outside the combustion body 500 to allow the external cooling tube 314 to rotate, and thus the internal cooling tube. A plurality of the removal blades 410 connected to the 312 to be linked to rotate.

To this end, the power transmission unit 370, the protruding gear 372 protruding on the outer surface of the external cooling pipe 314, the chain 374 connected to the protruding gear 372, and the chain 374 A connecting gear 376 connected to the protruding gear 372 and formed to face the protruding gear 372 and a motor 378 connected to the connecting gear 376 to rotate the connecting gear 376.

Here, the configuration of the power transmission unit 370 is only one embodiment, if the cooling body 300 can be smoothly rotated, it can be replaced with various components, such as pulleys and belts according to the needs of the user.

On the other hand, the cooling body 300, the following components in order to be rotated while cooling the internal cooling pipe 312 and the cleaner remover 400 entered into the combustion body 500. It includes more.

In addition, the cooling body part 300 may use water and air as a cooling catalyst to cool the internal cooling tube 312 and the clincher removing part 400.

When water is used as the cooling catalyst, the cooling body part 300 extends outwardly from the external cooling pipe 314 and circulates inside the cooling water 50 and the cooling housing 310 that enter from the outside. And a cooling compartment tank 320 for partitioning the cooling water 50 discharged to the outside.

Subsequently, the cooling body part 300 is connected to the cooling housing 310 and the cooling compartment tank 320 while the cooling compartment 310 is fixed when the cooling housing 310 is rotated. It has a joint 330 to maintain it.

The cooling body 300 is connected to the outer surface of the cooling compartment tank 320, the entry pipe 342 into which the cooling water 50 enters, and the cooling water 50 circulated inside the cooling housing 310. ) Has a supply drain pipe 340 consisting of a discharge pipe 344 is discharged.

The cooling body part 300 is connected to the inside of the cooling compartment tank 320 and connected to the inside of the cooling housing 310 while being connected to the entry pipe 342 and injected through the entry pipe 342. The cooling water 50 includes a cooling supply pipe 350 to be supplied to the inside of the cooling housing 310.

The cooling compartment tank 320, after the cooling water 50 injected through the entry pipe 342 enters the cooling supply pipe 350, the internal cooling pipe 312 and the external cooling pipe ( After circulating 314, a function of mutually isolating the cooling water 50 discharged to the discharge pipe 344 is performed.

The cooling housing 310 performs the function of cooling the clinker removal unit 400 and the internal cooling tube 312 while allowing the clinker removal unit 400 to rotate.

The joint 330 is formed between the cooling compartment tank 320 and the external cooling tube 314 of the cooling housing 310 so that the cooling compartment tank 320 is rotated when the cooling housing 310 is rotated. It will perform a function to maintain the stopped state.

In addition, the inside of the joint 330, the cooling supply pipe 350 is connected to the entry pipe 342 is formed from the inside of the outer cooling pipe 314 to the interior of the inner cooling pipe 312 is formed Is placed.

In addition, inside the joint 330, the cooling water 50 circulated through the cooling housing 310 may flow through the inside of the joint 330 along the outer diameter of the cooling supply pipe 350. To do so.

That is, the cooling supply pipe 350 supplies the cooling water 50 to the internal cooling pipe 312 while maintaining a fixed state, and the cooling housing 310 interferes with the cooling supply pipe 350. Without being rotated by the power transmission unit 370.

And, the lower portion of the outer cooling tube 314, at least one bearing support tube (362) to be rotatable while the cooling housing 310 is supported, and the bearing support at the lower portion of the bearing support tube (362) A support table 364 for supporting the tube 362 is disposed.

The bearing support tube 362 may support the cooling housing 310 while minimizing frictional force with the cooling housing 310 when the cooling housing 310 is rotated. .

At this time, the cooling body 300, the diameter of the inner cooling tube 312 is formed larger than the diameter of the outer cooling tube (314).

The reason why the diameter of the inner cooling tube 312 is formed larger than that of the outer cooling tube 314 is that the cooling water 50 entering the inner cooling tube 312 is transferred to the outer cooling tube 314. In the flow, the bottleneck is to slow down the discharge rate of the cooling water (50).

9 is a view showing a combustion facility equipped with a combustion furnace clinker removal device according to the present invention.

9, the combustion body portion 500, which is integrally formed on the outer surface of the combustion body portion 500, is divided in the vertical direction to form a plurality of layers while separately dispensing and injecting air in each layer to the combustion Cooling unit 600 for cooling the body portion 500 is formed.

And, connected to the upper portion of the combustion body portion 500 to suck the air entered into the combustion body portion 500 by the cooling unit 600 to form a negative pressure inside the combustion body portion 500 A negative pressure induction part 700 is formed.

In addition, the outer portion of the combustion body 500, the conveyor unit 535 for the solid fuel 10 is transferred, and the solid fuel 10 transferred from the conveyor unit 535 is introduced into the hopper ( A cylindrical cylinder portion 520 is formed to allow entry into 585.

In addition, a cylinder rod part 530 is formed to push and transport the solid fuel 10 introduced into the cylinder part 520 while reciprocating while being entered from the outside of the cylinder part 520.

In addition, the cooling unit 600, the air inlet 610 for injecting air into the combustion body portion 500 from the outside, and the flow rate for measuring the pressure of the air supplied to the cooling unit 600 The sensor 603 and an air conditioner 605 for adjusting the amount of air supplied to the cooling unit 600 in accordance with the pressure of the air measured by the flow sensor 603.

The combustion body part 500 includes a starter burner 570 which provides a flame in the combustion body part 500 so that the solid fuel 10 may be ignited, and thermal energy generated by the combustion furnace 500. It includes an energy exchange unit 575 to convert to steam or electricity.

On the other hand, the lower side of the combustion body portion 500, the entry mounting portion 510 is formed to be opened and closed.

And, the front end is placed into the combustion body portion 500 through the entry position 510 and the end is disposed outside the combustion body portion 500 to enter the combustion body portion 500. Cooling body 300 is provided to cool the portion through the circulation of water or air.

In addition, protruding to the outer surface of the cooling body portion 300 entered into the combustion body portion 500, the clinker removal unit 400 for removing the clinker 30 generated in the grate 590 Is formed.

In addition, it has a power transmission unit 370 connected to the cooling body portion 300 disposed outside the combustion body portion 500 to transmit power to rotate the cooling body portion 300.

In addition, the cooling unit 600 is formed integrally on the outer surface of the combustion body 500, partitioned in the vertical direction to form a plurality of layers while dispensing and injecting air separately in each layer to cool the combustion body 500. Has

In addition, it is connected to the upper portion of the combustion body portion 500 to suck the air entered into the combustion body portion 500 by the cooling unit 600 to form a negative pressure inside the combustion body portion 500 It includes a negative pressure induction unit 700.

On the other hand, the cooling unit 600 is provided while wrapping the outer wall of the combustion body portion 500 is connected to be laminated from the lower portion of the combustion body portion 500 to the upper side along the outer surface of the combustion body portion 500. Is placed.

When the solid fuel 10 is burned, a high heat of 1,000 ° C. or more is generated in the combustion body 500, and the high heat may damage parts around the combustion body 500.

Therefore, by cooling the outer surface and the inside of the combustion body portion 500, it is prevented that the parts surrounding the combustion body portion 500 is damaged.

Here, the combustion body part 500 and the cooling part 600 may be steel or various metals having strong heat resistance.

Particularly, heat-resistant metal is manufactured and used in casting form to minimize deformation by heat.

The cooling unit 600 is integrally formed on the outer surface of the combustion body portion 500, is divided in the vertical direction to form a plurality of layers while separately dispensing and injecting air in each of the combustion body portion 500 To cool.

In addition, the cooling unit 600, the function to prevent the heat transmitted to the outside and the inside of the combustion body portion 500 is discharged to the outside and to inject air into the combustion body portion 500 from the outside, The preheated air is input to simultaneously perform a function of increasing the combustion atmosphere in the combustion body 500.

When the combustion atmosphere in the combustion body portion 500 is increased in this way, the combustion efficiency is increased, thereby increasing the energy conversion efficiency.

On the other hand, when the heat is transmitted by the high pressure to the parts surrounding the combustion body 500, the parts are damaged in a short time, by adjusting this in order to prevent heat shock in advance to prevent the negative pressure induction unit 700 Will be used.

That is, the negative pressure induction unit 700 is used to maintain the air pressure of the combustion body 500 lower than the external air pressure.

The negative pressure induction part 700 is connected to an upper portion of the combustion body part 500 and sucks air entered into the combustion body part 500 by the cooling part 600 to the combustion body part 500. The negative pressure is formed inside.

Thus, through the negative pressure induction unit 700, since the air inside the combustion body portion 500 smoothly flows to the outside, the interior of the combustion body portion 500 to maintain the negative pressure, due to the positive pressure operation Inner and outer parts of the furnace can prevent damage.

On the other hand, the cooling unit 600, the flow sensor 603 for measuring the pressure of the air supplied into the cooling unit 600, and the cooling unit in accordance with the pressure of the air measured by the flow sensor 603 And an air conditioner 605 for adjusting the amount of air supplied to 600.

The combustion body part 500 includes a starter burner 570 which provides a flame inside the combustion body part 500 so that the solid fuel 10 may be ignited, and thermal energy generated by the combustion body part 500. It includes an energy exchange unit 575 for converting to steam or electricity.

On the other hand, the cooling unit 600, the flow sensor 603 for measuring the pressure of the air supplied into the cooling unit 600, and the cooling unit in accordance with the pressure of the air measured by the flow sensor 603 And an air conditioner 605 for adjusting the amount of air supplied to 600.

As the air conditioner 605, a flow regulator such as a damper or mass flow meter (MFC) may be used.

Here, the flow rate sensor 603, if the pressure of the air supplied to the cooling unit 600 can be measured so as to be connected to the inside from the outside of the combustion body portion 500 according to the user's convenience A plurality of cooling units 600 may be disposed in a multilayer.

Similarly, the flow rate sensor 603 may be variously disposed at a position desired by the user, if the pressure of the air supplied into the cooling unit 600 can be measured.

Meanwhile, the negative pressure induction part 700 includes a pressure sensor 609 for measuring the pressure in the combustion body 500 and a temperature sensor 601 for measuring the temperature in the combustion body 500. .

The pressure sensor 609 may be formed at each position of each of the cooling units 600 stacked in multiple layers in order to firmly measure the pressure difference between the inside and the outside of the combustion body 500.

In addition, the combustion body part 500 receives the flow rate value and the pressure value measured by the flow rate sensor 603 and the pressure sensor 609, and the air conditioner 605 according to the flow rate value and the pressure value. And a controller 502 for controlling the sound pressure induction part 700, and a transmitter 504 for transmitting the information measured by the temperature sensor 601 to the conveyor part 535.

Here, the temperature sensor 601 may be provided in each of the cooling units 600 stacked in multiple layers to measure temperature information for each part.

Here, the position and number of the flow sensor 603, the pressure sensor 609 and the temperature sensor 601 can be variously modified according to the needs of the user.

The conveyor unit 535 further includes a feed amount controller 560 that receives the information transmitted from the transmitter 504 and adjusts the supply amount of the solid fuel 10 transferred from the conveyor unit 535.

The transmitter 504 transmits the temperature information measured by the temperature sensor 601 to the conveyor unit 535, and the conveyor unit 535 supplies the supply amount based on the information transmitted from the transmitter 504. The controller 560 controls the conveyor unit 535.

That is, the supply controller 560 controls the amount of the solid fuel 10 supplied from the conveyor unit 535 to the cylinder unit 520, and is supplied into the combustion body 500. The amount of solid fuel 10 is adjusted.

In particular, the combustion body portion 500, the starter burner 570 to provide a flame inside the combustion body portion 500 so that the solid fuel 10 can be ignited, and in the combustion body portion 500 It includes an energy exchange unit 575 for converting the generated heat energy into steam or electricity.

The negative pressure induction part 700 may include a communication 710 connected to an upper portion of the combustion body 500, a sound pressure generator 720 connected to the communication 710, and the communication 710 and the sound pressure. A harmful gas treatment unit 730 is formed between the generator 720 to remove or decompose the combustion gas having gaseous harmful substances and particulate hazardous substances.

Here, the starter burner 570 may be arranged in various positions and forms according to a user's needs at the time of manufacture.

At this time, the energy exchange unit 575, by using the heat generated in the combustion body portion 500, can be used directly in a state converted to steam, or can be used to exchange the electricity using the steam. It performs the function that makes it possible.

The energy exchange unit 575, such as a boiler for converting energy through a generator may be used.

The noxious gas processing unit 730 is connected to the communication 710 but is formed between the energy exchange unit 540 and the negative pressure generator 720 to perform a function of decomposing or removing harmful gas.

As the noxious gas processing unit 730, an SNCR, an SCR, an SDR, a DR, a bag filter, or the like may be used.

The energy exchange unit 575 is operated by using the heat energy generated through the solid fuel 10 processing the waste fuel, thereby reducing the cost of using energy.

The lower part of the support body part 300 provided at the lower part of the combustion body part 500 supports the combustion body part 500, and a plurality of wheels for smooth movement of the combustion body part 500. 501 is formed.

The wheel 501 can be firmly fixed through the fastener 503 provided at the position adjacent to the wheel 501 during the operation of the combustion body 500.

Through the above configuration, when the inner wall of the combustion furnace is damaged, the inner wall of the combustion furnace can be partially replaced easily, so that an economical advantage of improving work efficiency and reducing replacement costs can be obtained.

Combustion equipment having a prefabricated combustion furnace according to the present invention, because it is possible to reduce the cost while reducing the installation time of the combustion furnace can obtain the economic advantages accordingly.

Combustion equipment having a prefabricated combustion furnace according to the present invention can increase the operating efficiency of the combustion furnace by preventing the failure of the combustion device by continuously removing the clinker deposited on each component of the furnace during the operation of the combustion furnace. There is an advantage of improving productivity.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Those skilled in the art will appreciate that various modifications and changes may be made thereto without departing from the scope of the present invention.

Therefore, the spirit of the present invention should not be limited to the embodiments described above, and all of the equivalents or equivalents of the claims, as well as the appended claims, are included in the scope of the spirit of the present invention. I will say.

10: solid fuel 30: clinker
50: coolant
100: assembly unit 110, 110 ': assembly plate
116: cooling flow groove
120, 120 ': bonding monolayer 130: bonding flange
150: cooling guide
200: connection unit 210: coupling protrusion
212: combining head 214: mounting piece
220: coupling groove 222: head groove
224: pin groove
230, 230 ': Nut groove
240: fastening groove 250: protrusion coupling groove
260: connecting frame 262: upper connecting frame
264: lower connection frame
300: cooling body 310: cooling housing
312: internal cooling tube 314: external cooling tube
320: cooling compartment tank 330: joint
340: supply drain pipe 342: entry pipe
344: discharge pipe
362: bearing support pipe 364: support table
370: power transmission unit 372: protruding gear
374: chain 376: connecting gear
378: motor
400: remover remover 410: removal blade
500: combustion body portion 502: controller
504: transmitter
510: entry portion 512: the first hermetic bearing
514: first sealed door 515: cooling inlet
516: second sealed bearing 518: second sealed door
520: cylinder portion 525: bearing
530: cylinder rod part
535: conveyor 560: supply controller
570: start burner 575: energy exchange unit
580: turntable 585: hopper
590: Grate
600: cooling unit 601: temperature sensor
603: flow sensor 605: air conditioner
609: pressure sensor
700: sound pressure induction part 710: communication
720: negative pressure generator 730: harmful gas processing unit

Claims (12)

An assembly unit 100 in which a plurality of pieces are assembled together to form an inner wall of the combustion furnace so as to form a combustion furnace that is a combustion space capable of producing thermal energy as the solid fuel 10 enters and is combusted;
A connection unit 200 allowing the assembly units 100 to be coupled or separated from each other; And
The grate 590 for supporting the solid fuel 10, and disposed below the grate 590 and has an annular shape, the turntable 580 for rotating the grate 590, the assembly unit And a combustion body part 500 forming an outer wall of the combustion furnace while surrounding the connection part 200 and the connection part 200.
The assembly unit 100,
Including a plurality of plate-shaped assembly plate 110 is assembled to each other,
The connection unit 200,
A coupling protrusion 210 formed on an upper portion of the assembly plate 110 such that the assembly plates 110 may be coupled to or separated from each other;
Is formed in the lower portion of the other assembly plate 110 'includes a coupling groove 220, the coupling protrusion 210 is fitted,
A coupling single layer 120 having a single layer formed on each of the left and right sides of the building plates 110 and 110 'so that different building plates 110 and 110' overlap each other in a horizontal direction;
It includes a coupling flange 130 protruding in a horizontal direction on the lower portion of the assembly plate (110, 110 ') so that different assembly plates (110, 110') can be laminated in a vertical direction to each other,
The coupling groove 220,
Combustion equipment having a prefabricated combustion furnace, characterized in that formed on the lower portion formed with the coupling flange 130 of the assembly plate (110, 110 ').
The method of claim 1,
Under the combustion body portion 500,
It is provided with an access mounting portion 510 formed to be openable,
The tip is placed into the combustion body portion 500 through the entry position 510 and the end portion is disposed outside the combustion body portion 500 to enter the combustion body portion 500. Cooling body portion 300 and the cooling through the circulation of water or air,
And formed on the outer surface of the cooling body portion 300 entered into the combustion body portion 500, the clinker removal unit 400 for removing the clinker 30 generated in the grate 590,
Prefabricated, characterized in that the power transmission unit 370 is connected to the cooling body portion 300 disposed outside the combustion body portion 500 for transmitting power to rotate the cooling body portion 300 is provided. Combustion plant with combustion furnace.
The method of claim 1,
The combustion body portion 500,
Cooling unit 600 is formed integrally on the outer surface of the combustion body portion 500, partitioned in the vertical direction to form a plurality of layers while dispensing and injecting air separately in each layer to cool the combustion body portion 500;
Sound pressure is connected to the upper portion of the combustion body portion 500 to suck air entered into the combustion body portion 500 by the cooling unit 600 to form a sound pressure inside the combustion body portion 500 Combustion equipment having a prefabricated combustion furnace, characterized in that the induction part 700 is formed.
delete delete The method of claim 1,
The connection unit 200,
A plurality of nut grooves 230 and the nut grooves are formed at positions corresponding to the edges of the respective assembly plates 110 and 110 'so as to assist the different assembly plates 110 and 110' from being mutually detached. Combustion equipment having a prefabricated combustion furnace further comprising a fastening bolt 240 coupled to or separated from 230.
The method according to claim 1 or 6,
The connection unit 200,
When the vertical assembly of the different assembly plates (110, 110 '), further comprises an annular connecting frame 260 formed between the different assembly plates (110, 110') to be connected to each other detachable,
The connecting frame 260,
An upper connection piece 262 extending upward from the connection frame 260,
It includes a lower connection piece 264 extending in the downward direction in the connecting frame 260,
The upper connection piece 262, the nut groove 230 is further provided,
Combustion equipment having a prefabricated combustion furnace, characterized in that the lower connection piece 264, the coupling groove 220 is further provided.
The method of claim 2,
The cooling body portion 300,
A rod-shaped internal cooling tube 312 and the rod-shaped internal cooling tube 312 which are arranged to enter the interior of the combustion body portion 500 through the entry position 510 and the combustion body portion 500 Cooling housing 310 consisting of a rod-shaped external cooling pipe 314 disposed on the outside of the;
Is formed extending outward from the external cooling pipe 314, partitioning the cooling material made of water or air entering from the outside for cooling and the cooling material discharged to the outside after being circulated in the cooling housing 310 Cooling compartment tank 320;
A joint 330 for interconnecting the cooling housing 310 and the cooling compartment 320 to maintain the fixed state of the cooling compartment 320 when the cooling housing 310 is rotated;
Supply drain pipe 340 is connected to the outer surface of the cooling compartment 320 is composed of an entry pipe 342 into which the cooling material enters and a discharge pipe 344 through which the cooling material circulated in the cooling housing 310 is discharged. ; And
The cooling material 310 connected to the entry pipe 342 and disposed to be connected to the inside of the cooling compartment 320 and the inside of the cooling housing 310 to be injected through the entry pipe 342 is the cooling housing 310. Combustion equipment having a prefabricated combustion furnace comprising; cooling supply pipe 350 to be supplied to the inside.
The method of claim 1,
The combustion body 500,
Prefabricated including a hopper (585) for supplying the solid fuel (10) to the inside of the combustion body 500 from the outside while the penetrates the grate (590) in the upward direction at the bottom of the turntable (580). Combustion plant with combustion furnace.
The method of claim 9,
Outside the combustion body 500,
A conveyor unit 535 for transferring the solid fuel 10,
A cylindrical cylinder portion 520 which allows the solid fuel 10 transferred from the conveyor portion 535 to enter the hopper 585, and
The prefabricated combustion furnace includes a cylinder rod part 530 for pushing and transporting the solid fuel 10 introduced into the cylinder part 520 while reciprocating while being entered from the outside of the cylinder part 520. Having combustion equipment.
The method of claim 3,
The cooling unit 600,
An air inlet 610 for injecting air into the combustion body 500 from the outside;
A flow rate sensor 603 for measuring a pressure of air supplied into the cooling unit 600;
Combustion equipment having a prefabricated combustion furnace including an air conditioning device for adjusting the amount of air supplied to the cooling unit 600 according to the pressure of the air measured by the flow sensor (603).
The method of claim 1,
The combustion body 500,
Starting burner 570 for providing a flame inside the combustion body 500 so that the solid fuel 10 can be ignited,
Combustion equipment having a prefabricated combustion furnace including an energy exchange unit 575 for converting the heat energy generated in the combustion body portion 500 to steam or electricity.

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