KR100451850B1 - Removal device for continuous-system fuel tank of combustor using circular type driving plate - Google Patents

Abstract

The present invention relates to a continuous fuel cell moving device for a combustion furnace using a circular rotating plate, and a circular rotary plate having three bogies and a fuel tank divided by 120 ° at a lower part of a main combustion furnace and an auxiliary combustion furnace installed on an upper surface of a main body of a combustion furnace has a rotary shaft. It is fixed to the lower part of the rotary wheel, and a plurality of rail wheels fixed to the bottom of the circular rotating plate is mounted on the guide rail fixed to the base of the lower part of the main body so that the circular rotary plate is rotated at the same time as the rotation of the rotating shaft. Hydraulic jacks are respectively installed on the pedestal of the main body at the bottom of the bogie to support and secure the fuel tank located at the bottom, so that the fuel tanks located at the lower part of the main combustion furnace and the auxiliary combustion furnace are lifted up and down simultaneously. After adding fuel, rotate the round rotor clockwise one third of each turn and By the operation is configured to be able to handle the waste incineration continuously through the after-ignition, air flow, fuel flow to the control was close contact with the peripheral cattle and secondary combustion.

Description

Removal device for continuous-system fuel tank of combustor using circular type driving plate}

The present invention injects fuel using waste rubber, waste synthetic resin, waste oil, food waste, etc. into a fuel container of a combustion furnace to burn waste in the main combustion furnace, and then burns the residual heat remaining in the main combustion furnace in the auxiliary combustion furnace. The present invention relates to a continuous fuel cell moving device for a combustion furnace using a circular rotary plate which allows to continuously incinerate wastes in the order of combustion and discharge of the combustion ash generated by the combustion of residual heat in the auxiliary combustion furnace.

Conventional batch-burning furnaces for incineration of wastes have been generally used in which a waste inlet and a combustion material outlet are separately installed in a combustion chamber and waste is introduced into the combustion chamber with the inlet open. It always existed, and if the backfire occurred when opening the inlet, there was a problem of worker's safety due to the high temperature flame, and in the case of leakage of combustion gas and environmental pollution, incomplete combustion, etc. In addition, if the temperature inside the combustion chamber suddenly rises due to overheating when the waste burns, the black smoke is released into the atmosphere due to incomplete combustion. Caused pollution, and the waste in the combustion chamber It is thereby of combustion at low temperatures were a lot of issues to promote a cleaner environment and the economic costs of treatment due to the remnants of combustible waste, so they remain as remnants of ash leave more than 10% of the total waste.

The present invention was devised to solve the above problems, and the main combustion furnace and the auxiliary combustion furnace are respectively installed on the upper surface of the main body of the combustion furnace, and one side of the main body is provided with a centrifugal dust collector and a boiler, and the communication and the main connection connected to the upper part thereof. It is installed to be connected with the connecting pipe connected to the furnace and the auxiliary combustion furnace, and the air supply pipe inlet connected to the main combustion furnace and the auxiliary combustion furnace in the tangential direction is installed, respectively, a blower is installed, the same configuration in the lower part of the main combustion furnace and the auxiliary combustion furnace The three bogies and the fuel tank are installed with a circular rotary plate that is divided into 120 °, and the hydraulic jack is installed on the base of the main body to support the fuel tanks located in the main combustion furnace and the auxiliary combustion furnace. It is configured to raise and lower the fuel tank located in the combustion furnace at the same time. After inserting the waste fuel into the fuel tank installed on the vehicle, rotate the circular rotary plate clockwise by 1/3 turn and operate the hydraulic jack to make the fuel cylinder close to the main and secondary combustion furnaces, and then centrifuge through ignition, blowing and control. The purpose of the present invention is to provide a combustion furnace that can continuously burn incinerators in the order of complete combustion and separate fuel input, combustion, residual heat combustion, and combustion material discharge in a separate combustion method.

1 is an overall perspective view of a combustion furnace according to the present invention,

2 is a plan view showing the main parts of the combustion furnace according to the present invention;

3 is a longitudinal cross-sectional view of the main portion of the present invention,

Figure 4a is a cross-sectional view showing the air flow for the main combustion furnace of the present invention,

Figure 4b is a cross-sectional view showing the air flow for the auxiliary combustion furnace of the present invention,

5a is a state in which the fuel container of the present invention is rotated,

5b is a state in which the fuel container of the present invention is rotated,

Figure 6 is a plan view showing the installation position of the hydraulic jack on the circular rotating plate of the present invention,

7 is a plan view showing the arrangement of the trolley on the circular rotating plate of the present invention,

Figure 8 is a longitudinal cross-sectional view showing a circular rotating plate coupling state of the present invention,

9 is a plan view showing a coupling state of the upper surface of the main body of the present invention.

<Explanation of symbols for main parts of drawing>

10: body 10a: stand

20: main combustion furnace 20a, 20b, 30a: air supply pipe

30: auxiliary combustion furnace 40: centrifugal dust collector and boiler

50: communication 60: connector

70: blower 80: bogie

90: fuel container 100: circular rotating plate

110: rotation axis 120: rail wheel

120a: Rail groove 130: Guide rail

140: hydraulic jack 200: combustion furnace

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

Figure 1 of the present invention is an overall perspective view of a combustion furnace according to the present invention, Figure 2 is a plan view showing the main portion of the combustion furnace according to the present invention, Figure 3 is a longitudinal cross-sectional view of the main portion of the present invention, Figure 4a is a present invention Figure 4b is a cross-sectional view showing the air flow for the main combustion furnace of the present invention, Figure 4b is a cross-sectional view showing the air flow for the secondary combustion furnace of the present invention, Figure 5a is a state diagram in which the fuel tank of the present invention is rotated, Figure 5b is a fuel tank of the present invention This is a rotated state diagram, Figure 6 is a plan view showing the installation position of the hydraulic jack on the circular rotating plate of the present invention, Figure 7 is a plan view showing the arrangement of the trolley on the circular rotating plate of the present invention, Figure 8 is a circular of the present invention Figure 9 is a longitudinal cross-sectional view showing a rotating plate coupling state, Figure 9 is a plan view showing a main body upper plate coupling state of the present invention.

In the present invention, the main combustion furnace 20 and the auxiliary combustion furnace 30 are respectively installed on the upper surface of the main body 10 of the combustion furnace 200, and the centrifugal dust collector and the boiler 40 are installed at one side of the main body 10, and the The upper part of the communication unit 50 and the main combustion furnace 20 on the upper surface of the main body 10 and the connecting pipe 60 installed in the auxiliary combustion furnace 30 are installed to communicate with each other, and the main combustion furnace 20 and the auxiliary combustion furnace ( Blowers 70 are respectively installed at the inlet of the air supply pipes 20a, 20b, and 30a connected to each other in a tangential direction, and the lower part of the main combustion furnace 20 and the auxiliary combustion furnace 30 have the same configuration. While the main truck 80 and the fuel tank 90 are divided into 120 °, the circular rotary plate 100 is fixed to the lower portion of the rotary shaft 110 rotatably installed in the center of the main body 10, but the bottom of the circular rotary plate 100 A plurality of rail wheels 120 are fixedly installed so that the rail grooves 120a of the rail wheels 120 are fixed to the pedestal 10a at the bottom of the main body 10. It is mounted so that the circular rotating plate 100 is rotated at the same time as the rotation of the rotary shaft 110, the bogie 80 for fixing the fuel tank 90 located in the main combustion furnace 20 and the auxiliary combustion furnace 30 The hydraulic jack 140 is installed on the pedestal (10a) of the main body 10 in the lower portion is configured to lift and lower the fuel tank 90 located at the lower portion of the main combustion furnace 20 and the auxiliary combustion furnace 30 at the same time.

In the figure, reference numeral 100a is a guide rod fixed on both sides of the circular rotating plate 100 to prevent the bogie 80 from being separated when the bogie 80 is lowered to the hydraulic jack 140, and 100b is a circular rotor plate. It is a partition wall installed and fixed between the fuel container 90 and the fuel container 90 on 100.

The present invention of such a configuration is located in front of the main body 10 opening (10b) and put the waste fuel to be incinerated in the fuel container 90 fixed on the bogie 80 of the circular rotating plate 100, the circular rotating plate (100) in the clockwise direction 1/3 (in this case, although not shown, the drive motor is installed in the lower portion of the main body 10 is connected to the rotating shaft 110 to rotate and stop the rotating shaft 110) to the main combustion When the hydraulic jack 140 is operated to raise the truck 80 at the same time after being positioned at the lower portion of the 20, the upper end of the fuel container 90 is in close contact with the lower end of the main combustion furnace 20 and the auxiliary combustion furnace 30. After the fuel cell 90, the main combustion furnace 20 and the auxiliary combustion furnace 30 and the abutting portion is sealed to the optimum state by ignition, blowing, and control the primary incineration by centrifugal combustion method, at this time, the main combustion furnace ( Fuel cell 90 positioned at the lower part of 20) and moved to the lower part of the auxiliary combustion furnace 30 This effect is achieved by the combustion state waste fuel is not supplied. When the waste fuel in the fuel tank 90 located below the main combustion furnace 20 is burned over 90% and becomes residual heat, the hydraulic jack 140 is lowered to lower the fuel tank 90 and the circular rotating plate 100 is rotated clockwise 1 /. After making three revolutions, the waste fuel is introduced into the empty fuel container 90 positioned at the lower portion of the auxiliary combustion furnace 30 and moved to the front of the opening portion 10b of the main body 10, and the circular rotary plate 100 If the clockwise 1/3 turn is located in the lower portion of the main combustion furnace 20, the remaining fuel remaining fuel tank 90 is automatically located in the lower portion of the auxiliary combustion furnace (30). Then, the hydraulic jack 140 is operated to raise the bogie 80 at the same time to seal the fuel container 90 in close contact with the lower part of the main combustion furnace 20 and the auxiliary combustion furnace 30 and to ignite, blow, It is controlled to burn by centrifugal combustion method. When the fuel in the main combustion chamber 20 is burned over 90% and becomes residual heat, and the residual heat of the auxiliary combustion furnace 30 is completely incinerated, the hydraulic jack 140 is lowered to lower the main combustion furnace 20 and the auxiliary combustion furnace 30. Lowering the fuel tank 90 and rotating the circular rotating plate 100 one-third clockwise, the fuel tank 90 located at the lower part of the auxiliary combustion path 30 is connected to the opening of the main body 10 of the opening 10b. The fuel tank 90 located in the front and located in the lower part of the main combustion furnace 20 is automatically located in the lower part of the auxiliary combustion furnace 30. At this time, if the remaining amount of residual heat is completely incinerated in the fuel container 90 which is moved to the front of the opening portion 10b of the main body 10, the waste fuel is added and filled, and if the amount of the residual amount is large, FIG. 5A. And one side of the fuel container 90 by rotating the fuel container 90 to 90 ° about the fixing pin 90b provided on the support 90a on both sides for supporting and fixing the fuel container 90 as shown in FIG. 5B. After fixing the fuel container 90 with the fixing ring 90c installed on the upper part, emptying the remnants inside the fuel container 90 to the outside and then again positioning it to fix the fuel container 90 and inject waste fuel. As described above, the coupling structure for fixing the fuel cell 90 while rotating the fuel cell 90 by 90 ° when emptying the residue in the fuel cell 90 is a common configuration. In addition, the circular rotating plate 100 is to be smoothly rotated while supporting the weight of the weight by the rail wheel 120 and the guide rail 130.

Therefore, the present invention can incinerate waste continuously in alternating order of fuel input, combustion, residual heat combustion, and combustion material discharge in the combustion furnace 200 in the same manner as described above.

On the other hand, the exhaust gas generated when the combustion in the main combustion furnace 20 and the auxiliary combustion furnace 30 as described above is introduced into the centrifugal dust collector and boiler 40 while rotating through the connecting pipe (60). At this time, a blower 70 for supplying combustion air is installed at the inlet of the air supply pipes 20a, 20b, 30a connected tangentially to the outer walls of the main combustion furnace 20 and the auxiliary combustion furnace 30. Combustion air flows while rotating to swirl waste and residual heat by swirling by centrifugal combustion method, and the exhaust gas introduced into the centrifugal dust collector and boiler 40 collects foreign substances and harmful substances, and then clean exhaust gas only. It can be released to the atmosphere through the communication (50).

According to the present invention configured as described above, three fuel tanks are moved simultaneously by a circular rotary plate, so that the waste can be completely incinerated continuously in the order of fuel input, combustion, residual heat combustion, and combustion material discharge, thereby increasing the incineration efficiency of the waste. It is possible to continuously recover and use heat, and during incineration, the combustion gas in the main combustion furnace and the auxiliary combustion furnace is completely blocked from the outside, so there is no fear of leaking to the outside. Since it is located in the space part, there is no risk of fire and backfire, so the worker can safely incinerate the waste, and since the waste and residual heat are sequentially burned by the centrifugal combustion method, the temperature inside the combustion furnace suddenly rises or is incomplete. Risk of explosion due to no risk of burning In addition to this, only the clean exhaust gas can be discharged into the atmosphere through a centrifugal dust collector and a boiler, and in the case of the conventional batch-type batch type combustion furnace, the normal incineration time and the residual heat treatment time are consumed almost incinerated. The present invention provides a useful effect of completely burning residual heat in an auxiliary combustion furnace which is a separate space, and allowing residue processing and waste fuel to be introduced in the front space of the main body opening.

Claims (1)

The main combustion furnace 20 and the auxiliary combustion furnace 30 are respectively installed on the upper surface of the main body 10 of the combustion furnace 200, and the centrifugal dust collector and the boiler 40 are installed at one side of the main body 10 to communicate with the upper portion thereof. 50 and the main combustion furnace 20 on the upper surface of the main body 10 and the connecting pipe 60 installed in the auxiliary combustion furnace 30 are installed in communication with each other, the main combustion furnace 20 and the auxiliary combustion furnace 30 In the inlet of the air supply pipes 20a, 20b and 30a connected in the tangential direction, respectively, a blower 70 is installed, and three trucks 80 are provided below the main combustion furnace 20 and the auxiliary combustion furnace 30. And the fuel tank 90 is fixed to the lower portion of the rotating shaft 110 is installed rotatably installed in a central portion of the rotary plate 100 is 120 °, the bottom of the circular rotating plate 100, a plurality of rail wheels ( 120 is fixedly installed so that the rail groove 120a of the rail wheel 120 is mounted on the guide rail 130 fixed to the pedestal 10a below the main body 10. At the same time as the rotary shaft 110 is rotated, the circular rotary plate 100 is installed to rotate, and a hydraulic pressure is provided below the bogie 80 that supports and secures the fuel tank 90 positioned in the main combustion furnace 20 and the auxiliary combustion furnace 30. The jack 140 is installed in the pedestal (10a) of the main body 10, respectively, the circular shape characterized in that the fuel tank 90 located in the lower portion of the main combustion furnace 20 and the auxiliary combustion furnace 30 is raised and lowered at the same time Continuous fuel cell moving device for combustion furnace using rotating plate.