KR20170108181A - Vertical distribution type regenerative thermal oxidizer insert distribution rotor - Google Patents

Abstract

The present invention relates to a vertical distribution type heat accumulating combustion facility in which a distribution rotor is embedded, which is formed in a vertical distribution type, allows a distribution rotor to be inserted into a distribution layer and installed therein, lowers the overall height of the facility by allowing untreated gas to be supplied to the vertical distribution rotor after being sucked in the axial direction of a rotor housing through the distribution rotor inserted into the distribution layer and installed therein and the rotor housing provided on a lower portion of the distribution rotor, and to be supplied to the axial direction of the distribution rotor again, and which can ensure ease of sealing and manufacturing. The vertical distribution type heat accumulating combustion facility of the present invention comprises: a combustion chamber of which an upper side is provided with at least one combustion burner; a heat accumulating layer which is provided at a lower portion of the combustion chamber and divided into a plurality of heat accumulating chambers by partitions; a distribution layer which is provided at a lower portion of the heat accumulating layer to correspond to shapes of the heat accumulating layer and the heat accumulating chambers, and which has a plurality of distribution chambers to correspond to each of the heat accumulating chambers of the heat accumulating layer; and a distribution device in which a distribution rotor is vertically embedded and installed to protrude to an upper side of a center of the bottom of the distribution layer, and which supplies untreated gas to each of the distribution chambers of the distribution layer by driving the distribution rotor or discharges treated gas to the outside of the distribution rotor.

Description

TECHNICAL FIELD [0001] The present invention relates to a vertical distribution type regenerative thermal combustion apparatus,

The present invention relates to a distribution rotor embedded type vertical distribution heat accumulation combustion apparatus, more particularly, to a vertical distribution type regenerative combustion apparatus in which a distribution rotor can be inserted and installed inside a distribution layer, The untreated gas is sucked in the lateral direction of the rotor housing through the rotor housing provided together with the lower portion of the distribution rotor, and then supplied to the vertical distribution rotor, The present invention relates to a distributor rotor embedded type vertical distribution type heat accumulation combustion apparatus capable of supplying a gas without increasing the overall height of the facility and ensuring ease of sealing and fabrication.

Generally, a regenerative oxidation apparatus for treating volatile organic compounds (VOC's) generated in factories is divided into a regenerative thermal oxidizer (RTO) and a regenerative catalytic oxidizer (RCO) The oxidation facility includes a combustion chamber having at least one combustion burner on the upper side, a heat storage layer provided below the combustion chamber, and a plurality of distribution chambers arranged in the longitudinal direction by a partition plate, Is provided.

In addition, a distribution pipe is arranged in a center of a plurality of dispensing chambers provided at predetermined equally spaced intervals in the main body of the apparatus. The distribution pipe has elongated slots of predetermined equi-angular shape on the outer periphery of each dispensing chamber section, The distribution wing is mounted in the longitudinal direction. On the upper and lower sides of the distribution pipe, a diaphragm is disposed, and the purified and unburned gas is not mixed with the purified and unburned gas.

As shown in FIGS. 1 to 3, the introduction of the harmful gas inflow space 43 and the clean gas The discharge space 44 and the purge space 45 are partitioned into concentric partition walls 41 and 42. The inflow space 43 and the discharge space 44 and the purge space 45 are formed with inlet ducts 8), a discharge duct (9) and a purge pipe (10) are connected to each other; A plurality of regenerative chambers 22 provided in the upper side of the distribution housing 4 and having a regenerative material 24 are defined by radial diaphragms 26, And a regenerative combustion chamber 2 in which an upper space serves as a combustion chamber 23. A horizontal rotary plate 18 is provided between the distribution housing 4 and the regenerative combustion chamber 2, The inflow space 18 and the inflow space 18 are formed in the inflow space 43 and the discharge space 44 of the distribution housing 4 and the upper side of the purge space 45, The rotary shaft 16 of the horizontal rotary plate 18 is connected to the driving means through the central portion of the distribution housing 4, The regenerative burning and oxidizing apparatus is provided with a combustion burner (6) inserted into the combustion chamber (23) The lower end of the regenerative combustion chamber 2 is inserted through the upper surface of the distribution housing 4 to a certain depth and the lower end of the regenerative combustion chamber 2 is connected to the upper end of the distribution housing 4 Upper and lower support plates 34 and 47 are provided in the form of frame frames for supporting the rotation of the horizontal rotary plate 18. The upper and lower support plates 34 and 47 are provided with oil distributing housings 4, And the metal ring 19 is fixedly attached to the horizontal rotary plate 18 so that the metal ring 19 is in close contact with the horizontal rotary plate 18. The lower portion of the distribution housing 4 is provided with driving means A drive motor 14 having a speed reducer 15 and a lifting mechanism 5 of a distribution housing 4 are installed.

The gap between the inflow passage 18a formed in the horizontal rotary plate 18 and the discharge passage 18b and the purge passage 18c is provided to cover at least one regenerative chamber 22, An air flow distribution plate 28 provided with an air flow distribution hole 28a is installed in the form of a cover plate under each regenerative chamber 22 partitioned in the regenerative combustion chamber 2, The diaphragm 26 for partitioning the respective heat accumulating chambers 22 is provided so as to extend to a position higher than the heat accumulating material 24 and an opening and closing valve 77 is provided on the upper end side of the regenerative burning chamber 2 And the bypass pipe 7 is connected to the communication pipe 76 serving as a passage for exhaust air. A pilot burner 62 and a compressed air injection means are installed in the combustion burner 6 inserted into the combustion chamber 23 through the wall of the regenerative combustion chamber 2. The bypass pipe 7 is provided with a heat exchanger 78 at a position between the opening and closing valve 77 and the communication port 76. A catalytic processor 79 are installed.

However, in such a conventional rotary heat accumulation combustion and oxidation apparatus, since the distribution rotor is provided separately from the upper distribution chamber and the regenerative chamber, the entire facility is required to be made as high as the whole, so that the facility can not be miniaturized and sealing is difficult , There is a disadvantage in terms of price competitiveness due to lack of economical efficiency due to an increase in production unit price due to difficulty of production.

Registered Patent No. 0918880 (September 28, 2009) "Rotary Thermal Storage Combustion and Oxidation Treatment Apparatus"

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and it is an object of the present invention to provide a vertical distribution type heat accumulation type combustion apparatus capable of inserting and installing a distribution rotor into a distribution layer, The untreated gas is sucked in the lateral direction of the rotor housing through the rotor of the distributing rotor and the rotor housed in the lower portion of the distributing rotor and then supplied to the vertical distributing rotor, The present invention provides a distributing rotor embedded type vertical distribution type heat accumulation combustion apparatus which can lower the overall height of the facility and assure ease of sealing and fabrication.

To achieve these and other advantages and in accordance with the purpose of the present invention, as embodied and broadly described herein, there is provided a vertical distribution heat accumulation type combustion apparatus comprising: a combustion chamber having a combustion burner on an upper side thereof; A heat storage layer provided at a lower portion of the combustion chamber and partitioned into a plurality of heat storage chambers by barrier ribs; A distribution layer provided at a lower portion of the heat storage layer corresponding to the shape of the heat storage layer and the heat storage chamber and having a plurality of distribution chambers corresponding to the heat storage chambers of the heat storage layers; A distribution rotor is vertically installed so as to protrude upward from a bottom center portion of the distribution layer and a distribution which distributes untreated gas to a distribution chamber of each of the distribution layers by driving of the distribution rotor or discharges the process gas to the outside of the distribution rotor And a device.

The distributing device includes an inlet port and an outlet port formed in a lateral direction of one side and the other side, a distribution plate integrally formed on an upper surface between the inlet port and the outlet port, the distribution plate having a plurality of distribution plate inner distribution holes And a rotor housing having a distribution plate outer distribution hole formed therein; A plurality of distribution rotor inner distribution holes and a distribution rotor outer distribution hole are formed on a lower surface of the distribution rotor, A plurality of gas discharge holes are formed on one side of the upper surface between the chamber and the neutral chamber, the other upper surface of the gas discharge hole is closed by an upper shield plate, a plurality of side wall gas supply holes are formed on a lower side surface of the upper shield plate, A distribution rotor partitioned by an inner distribution pipe between the plurality of distribution rotor inner distribution holes and the distribution rotor outer distribution holes; A lower flange is connected to and coupled to a distribution plate of the rotor housing, a first supporter having an annular horizontal plate shape spaced apart from the lower flange is provided on the outside of the distribution rotor, The upper plate, the first supporter and the lower flange are integrally connected to each other by a second supporter formed in a plurality of concentric circles spaced apart from each other and vertically bent, And a plurality of frame upper distribution holes and a frame side distribution hole are formed between the upper plate and the first supporter, the lower flange, and the second supporter.

Further, the heat storage layer and the distribution layer are composed of a plurality of heat storage chambers and a distribution chamber having a quadrangular shape as a whole and having a quadrangular shape by partition walls and a partition wall, The supply of the untreated gas and the discharge of the process gas into the dispensing chamber of the dispenser are performed.

As described above, according to the present invention, a heat storage layer of a facility main body is formed in a rectangular or square shape, and a plurality of chambers are formed in a square lattice form using a transverse bulkhead and a longitudinal bulkhead in the heat storage layer, It is possible to secure the economical efficiency due to the downsizing of the facility and the cost reduction as well as the installation in a narrow space, and the chambers are formed in a square grid shape, so that the rectangular- It can be installed horizontally as it is fixed, and it is possible to diversify the shape according to installation environment conditions and to further increase the efficiency of space utilization.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a vertical sectional view showing the overall configuration of a distributing rotor embedded type vertical distribution heat accumulation combustion apparatus according to the present invention; FIG.
Figure 2 is a plan view of the distribution layer of Figure 1;
3 is a plan view showing the heat storage layer of FIG. 1;
4A-5 illustrate the dispensing apparatus of the present invention,
4A is a perspective view showing a state of engagement;
4B is an exploded perspective view.
5 is a longitudinal sectional view showing a coupled state.
6 to 8 show a conventional rotary heat accumulation combustion and oxidation apparatus,
6 is a partially exploded perspective view showing the internal structure of the regenerative combustion chamber;
7 is an exploded perspective view of the regenerative combustion chamber.
8 is an explanatory view of the state of use.

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

FIG. 1 is a longitudinal sectional view showing the overall configuration of a distributing rotor embedded type vertical distribution heat accumulation combustion apparatus according to the present invention. As shown in FIG. 1, the present invention includes a combustion chamber 110 having at least one combustion burner, A heat storage layer 120 having a plurality of heat storage chambers 122 is formed at a lower portion of the combustion chamber 110 by barrier ribs 121 and a heat storage layer 120 is formed below the heat storage layer 120, A distribution layer 130 having a plurality of distribution chambers 133 is formed corresponding to the shape of the layer 120 and the regenerative chamber 122.

The present invention is also characterized in that a distribution device D is provided below the distribution layer 130 to supply untreated gas to the distribution chambers 133 of the distribution layers 130 or to discharge process gas to the outside, And the distributing rotor 150 is vertically installed so as to protrude upward from the bottom center portion of the distribution layer 130 so that gas can be distributed. Reference numeral 150a denotes a central axis of the distribution rotor 150. Reference numeral 170 denotes a drive unit for rotationally driving the center shaft 150a. Reference numeral 170 denotes a drive motor. Reference numeral 171 denotes a drive motor that transmits power of the drive motor to the center shaft 150a .

FIG. 2 is a plan view showing the distribution layer of FIG. 1, and FIG. 3 is a plan view of the heat storage layer of FIG. 1, in which the distribution layer 130 has a rectangular shape as a whole, A plurality of distribution chambers 133 are formed in a rectangular shape and a distribution apparatus D is provided at a central portion of the distribution layer 130 and a plurality of distribution chambers 133 are provided between the distribution apparatus D and the distribution chamber 133 And is configured such that the untreated gas and the process gas are supplied to the heat storage layer 120 or discharged to the distribution rotor 150 side by communicating with each other by the duct 132 and toward the respective distribution chambers 133. In addition, the heat storage layer 120 has a plurality of heat storage chambers 122, which are generally quadrangular in shape, like the distribution layer 130, and are also rectangular in shape by barrier ribs 121, A heat storage material 123 having a rectangular shape corresponding to the heat storage chamber 122 is embedded. Therefore, it is possible to mount the heat accumulating material without any space or blank space between the heat accumulating materials. Therefore, it is advantageous that it can be installed and used horizontally as well as horizontally installed and used.

FIG. 4A is a perspective view illustrating a coupling state of the dispensing apparatus according to the present invention, FIG. 4B is an exploded perspective view thereof, and FIG. 5 is a longitudinal sectional view illustrating a coupled state. As shown, the distribution apparatus D of the present invention comprises a rotor housing 140, a distribution rotor 150, and a distribution frame 160. At this time, the distribution frame 160 protrudes upward from the center of the bottom of the distribution layer 130, and a distribution rotor 150 is disposed inside the distribution frame 160. The distribution frame 160 is divided by the rotor housing 140, The frame 160 and the lower portion of the distribution rotor 150 are supported.

The rotor housing 140 is provided with an intake port 141 and an exhaust port 142 in the lateral direction of one side and the other side of the rotor housing 140. On the upper surface between the intake port 141 and the exhaust port 142, A plurality of distribution plate inner distribution holes 143a and a distribution plate outer distribution hole 143b are formed concentrically with each other.

The distribution rotor 150 is disposed on the distribution plate 143 of the rotor housing 140 and receives power from the driving unit 170 to be rotated and driven about a vertical center shaft 150a, A plurality of distributing rotor inner distribution holes 153a and a distribution rotor outer distribution hole 153b are formed in the distributing rotor purge chamber 151 and the neutral chamber 152. A plurality of gas discharge holes 154 The other upper surface of the gas discharge hole 154 is closed by an upper shield plate 155 and a plurality of side wall gas supply holes 156 are formed on a lower side surface of the upper shield plate 155 And between the distribution rotor inner distribution holes 153a and the distribution rotor outer distribution holes 153b is partitioned by an inner distribution pipe 157. [

The distribution frame 160 is connected to the lower flange 161 on the distribution plate 143 of the rotor housing 140 and has an annular horizontal plate- A first supporter 162 is provided on the outer side of the distribution rotor 150 and an annular upper plate 163 is provided on the upper side of the first supporter 162 with an interval therebetween, The first supporter 162 and the lower flange 161 are integrally connected to and formed by a second supporter 164 formed in a concentric shape at a plurality of spaced apart and vertically bent vertical plates, A plurality of frame upper distribution holes 165 and a frame side distribution hole 166 are formed between the first supporter 162 and the lower flange 161 and the second supporter 164.

5, the untreated gas is sucked through the inlet 141 formed in the lateral direction of the rotor housing 140. The untreated gas is sucked into the vertical distribution plate 143 . The untreated gas having passed through the distribution plate inner distribution hole 143a of the distribution plate 143 and the distribution plate outer distribution hole 143b and then moved toward the distribution plate outer distribution hole 143b is again supplied to the distribution rotor 150 The sidewall gas supply holes 156 and the frame side distribution holes 165 and the ducts 132 of the distribution frame 160 are supplied to the distribution chambers 133 of the distribution layers 130, Exchanged through the chamber 122, and then sent to the combustion chamber 110 for combustion.

The process gas thus burnt passes through the regenerating chamber 122 of each of the regenerating layers 120 to perform heat exchange and the heat exchanged process gas is supplied to the distribution frame 160 through the distribution chamber 133 of each of the distribution layers 130. [ The distribution rotor 150 is introduced into the distribution rotor 150 through the frame side distribution holes 165 and the gas discharge holes 154 formed on the upper surface of the distribution rotor 150 and then distributed to the distribution rotor inner distribution holes 153a The air is discharged to the rotor housing 140 through the inner distribution hole 153a of the plate 143 and then discharged to the side of the exhaust port 142 of the rotor housing 140 again.

Thus, the present invention is such that the distribution rotor is embedded inside the upper portion of the bottom center portion of the distribution layer, the unprocessed gas is introduced laterally through the inlet port of the rotor housing, then vertically into the distribution rotor, The unprocessed gas is supplied to the side of the distribution layer and the heat storage layer and is combusted in the combustion chamber so that the height of the equipment can be lowered so that the size of the device can be reduced and the sealing frame It is advantageous in terms of economy as well as price competitiveness due to reduction in manufacturing cost due to its simple and easy fabrication and processing.

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 exemplary embodiments, The range is determined and limited. It will be apparent to those skilled in the art that various changes and modifications can be made by those skilled in the art without departing from the scope of the present invention.

100: Facility body 110: Combustion chamber
120: heat storage layer
121: partition wall 122: heat storage chamber
123: Heat storage material
130: distribution layer
131: compartment wall 132: duct
133: distribution chamber
140: rotor housing
141: intake port 142: exhaust port
143: Distribution plate 143a: Distribution plate Inner distribution hole
143b: distribution plate outer distribution hole
150: distribution rotor
150a: center axis 151: distribution rotor purge ball
152: distribution rotor neutral hole 154: gas discharge hole
155: upper blocking plate 156: side wall gas supply hole
157: inner distribution pipe 157a: guide surface
160: distribution frame
161: lower flange 162: first supporter
163: upper plate 164: second supporter
165: frame upper distributing hole 166: frame side distributing hole
170:
171: drive motor 172: power transmission part
D: Distribution device

Claims (3)

A combustion chamber (110) having at least one combustion burner on the upper side;
A heat storage layer 120 provided below the combustion chamber 110 and partitioned into a plurality of heat storage chambers 122 by barrier ribs 121;
And a plurality of distribution chambers 133 corresponding to the heat storage layers 120 and corresponding to the heat storage chambers 122 and corresponding to the heat storage chambers 122 of the heat storage layers 120, A dispensing layer 130 having a plurality of nozzles 130;
A distribution rotor 150 is installed vertically so as to protrude upward from a bottom center portion of the distribution layer 130 and the unprocessed gas is supplied to each of the distribution chambers 133 of the distribution layers 130 by driving the distribution rotor 150. [ And a distribution device (D) for supplying the process gas or the processing gas to the outside of the distribution rotor (150).
The method according to claim 1,
The distribution device D is provided with an intake port 141 and an exhaust port 142 in the lateral direction of one side and the other side and a distribution plate 143 integrally formed on the upper surface between the air inlet 141 and the air outlet 142 And the distribution plate 143 includes a rotor housing 140 having a plurality of distribution plate inner distribution holes 143a and a distribution plate outer distribution hole 143b concentrically formed therein;
And is disposed on the distribution plate 143 of the rotor housing 140 and receives power from the driving unit 170 and is rotated and driven about a vertical center shaft 150a. A plurality of gas discharge holes 154 are formed on one side of the upper surface between the distribution rotor purge chamber 151 and the neutral chamber 152, The upper side of the upper shield plate 154 is closed by the upper shield plate 155 and a plurality of sidewall gas supply holes 156 are formed in the lower side of the upper shield plate 155, A distribution rotor 150 partitioned by an inner distribution pipe 157 between the distribution rotor outer distribution hole 153a and the distribution rotor outer distribution hole 153b;
A lower flange 161 is connected and coupled on the distribution plate 143 of the rotor housing 140 and a first supporter 162 having an annular horizontal plate and spaced apart from the lower flange 161 And an annular upper plate 163 is provided on the upper side of the first supporter 162 and spaced apart from the upper side of the distribution rotor 150. The upper plate 163 and the first supporter 162, The flanges 161 are connected and formed integrally with each other by a second supporter 164 formed in a concentric circular form and spaced apart from each other by a vertical plate and bent in a vertical direction to form the upper plate 163 and the first supporter 162, And a plurality of frame upper distribution holes (165) and a frame side distribution hole (166) are formed between the lower flange (161) and the second supporter (164).
Wherein the distributor rotor embedded type vertical distribution type heat accumulation combustion apparatus is constituted by:
3. The method according to claim 1 or 2,
The heat storage layer 120 and the distribution layer 130 have a plurality of heat storage chambers 122 and a distribution chamber 133 having a square shape as a whole and having a rectangular shape by barrier ribs 121 and partition walls 131 And the distribution layer 130 is configured to supply the untreated gas to the respective distribution chambers 133 and discharge the process gas through the duct 132 around the distribution frame 160 One distribution rotor embedded type vertical distribution heat accumulation combustion facility.

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