KR102411851B1 - Distribution rotor for Horizontal Type Rotor Distributor of Regenerative Thermal Oxydizer - Google Patents

Abstract

According to the present invention, the front and rear surfaces of the distribution rotor with respect to the flange of the first housing and the distribution plate of the second housing are made of a packing material with excellent heat resistance and durability so that airtightness can be achieved by line contact, so that the flange of the distribution rotor and the first housing And as it relates to a distribution rotor for a rotor distributor of a thermal storage oxidation facility that reliably improves the airtightness between the distribution plates of the second housing, and enables maintenance and repair according to the wear of the hermetic packing and adjustment of the gap between the distribution rotors easily, The configuration is a cylindrical body to form the rotor body, and the inside of the rotor body is provided with distribution wings at equal intervals on the radiation centering on the front and rear central shaft holes, so that the neutral and purge parts are symmetrical to each other and supplied and discharged to both left and right sides. A supply distribution space and a discharge distribution space are formed for In the distribution rotor for a rotor distributor of a thermal regenerative oxidation facility in which a neutral hole and a purge hole partitioned to communicate with the distribution space and a plurality of supply holes and discharge holes are formed, the shaft pipe protrusions A, B toward the outer front side of the front and rear central shaft holes of the rotor body to form, along the front and rear outer periphery of the rotor body, annular support jaws A and B forming the same plane as the outer surface of the rotor body, and the annular first airtight packing on the outside of the shaft tube protrusions A and B It is formed to protrude somewhat from the protrusions A and B, and an annular second airtight packing is formed to slightly protrude from the annular supporting jaws A and B on the outside of the annular support jaws A and B, and the first airtight packing and the first airtight packing 2 It is to be provided with a first surface airtight packing and a second surface airtight packing in the same area on the front part of the neutral part and the purge part between the shaft tube projections A and B and the supporting jaws A and B so as to form the same plane as the two airtight packings.

Description

Distribution rotor for Horizontal Type Rotor Distributor of Regenerative Thermal Oxydizer

The present invention relates to a distribution rotor for a rotor distributor of a thermal storage oxidation facility, and more particularly, with respect to the flange of the first housing and the distribution plate of the second housing, the front and rear surfaces of the distribution rotor are made of a material having excellent heat resistance and durability. By ensuring airtightness by contact, the airtightness between the distribution rotor and the flange of the first housing and the distribution plate of the second housing is surely improved, and maintenance and repair according to the abrasion of the airtight packing and the adjustment of the gap between the distribution rotor are facilitated. It relates to a distribution rotor for a rotor distributor of a thermal regenerative oxidation facility.

In general, regenerative thermal combustion facilities that treat volatile organic compounds (VOC's) generated in factories are roughly divided into regenerative thermal oxidizer (RTO) and regenerative catalytic oxidizer (RCO), and usually regenerative catalytic oxidation equipment is a facility in which a plurality of distribution chambers are arranged in the longitudinal direction by a combustion chamber having at least one combustion burner on the upper side, a heat storage layer provided on the lower side of the combustion chamber, and a plurality of partition plates mounted at predetermined equal intervals on the lower side of the heat storage layer A body is provided.

In addition, the distribution pipe is disposed to pass through the center of a plurality of distribution rooms provided at regular intervals in the facility body, and the distribution pipe has long holes formed at a predetermined equal angle on the outer periphery for each distribution room section, and radially between the long holes on the inside. The distribution blades are mounted in the longitudinal direction. In addition, a diaphragm is disposed on the upper and lower sides of the distribution pipe to prevent mixing of the purified processed gas and the non-combusted untreated gas.

In addition, a rotor distributor having a distribution rotor is disposed on one side of the equipment body, and an example of the rotor distributor is Patent No. 0524290 (published on October 26, 2005) "Separable distribution rotor and rotor distributor adopting this distribution rotor" has been proposed

As shown in FIGS. 1 to 3, the rotor distributor 50 includes a first housing 10, a second housing 30, a first distribution rotor 50a and a second distribution rotor 50b. ), an elastic member 80 interposed between the first distribution rotor 50a and the second distribution rotor 50b, and a shaft 70 supporting the distribution rotor 50 . The shaft 70 rotates the distribution rotor 50 by receiving the rotational power of the driving unit 90 .

The first housing 10 includes a first casing 11 having a processing gas exhaust chamber 11a with one side open, and a processing gas exhaust duct communicating with the processing gas exhaust chamber 11a of the first casing 11 . (13), and a purge air supply duct (15) disposed in the processing gas discharge chamber (11a). A flange 17 in which a processing gas discharge hole 17a is partitioned is installed on the front surface of the first casing 11 , and a purge air supply duct 15 is fixed on the flange 17 . A shaft support hole for rotatably supporting a shaft 70 to be described later is perforated at the center of the first casing 11 and an end of the purge air supply duct 15 . A purge air supply hole 15b communicating with the purge air supply chamber 15a is partitioned in the purge air supply duct 15 around the shaft support hole.

The second housing 30 includes a second casing 31 having an untreated gas supply chamber 31a having both sides open, and an untreated gas supply duct communicating with the untreated gas supply chamber 31a of the second casing 31 ( 33) is composed. One side of the second casing 31 is fastened to the flange 17 of the first casing 11, and the other side of the second casing 31 is a distribution plate 40 that is fastened and fixed to the distribution pipe of the thermal storage and combustion facility. will be concluded on

As shown in FIG. 1 , the distribution plate 40 has a plurality of sector-shaped openings corresponding to the distribution chamber of the distribution pipe, and distributes and guides untreated gas, purge air, and treated gas. The distribution rotor 50 is divided into a first distribution rotor 50a and a second distribution rotor 50b disposed in the second casing 31 . The first distribution rotor 50a has a cylindrical body 51a, a shaft portion 53a that is disposed at the center of the cylindrical body 51a and is spline-coupled to the shaft 70, and the shaft portion 53a is disposed and installed on the outer periphery of the purge air It consists of a purge air supply pipe 55a communicating with the supply hole 15b, and a first fastening part 57a installed on the outer periphery of the purge air supply pipe 55a. The purge air supply pipe 55a and the cylindrical body 51a are connected by an arm 59a. The treated gas passes between the arm 59a and the arm 59a.

The second distribution rotor 50b also has a cylindrical body 51b, similar to the first distribution rotor 50a, disposed at the center of the cylindrical body 51b and spline-coupled to the shaft 70. A shaft portion 53b, a shaft portion 53b ) is disposed on the outer periphery and is composed of a purge air supply pipe 55b communicating with the purge air supply pipe 55a, and a second fastening part 57b installed on the outer periphery of the purge air supply pipe 55b. The purge air supply pipe 55b and the cylindrical body 51b are connected by an arm 59b. Unprocessed gas, purge air, and processed gas flow between the arm 59b and the arm 59b.

In the cylindrical body 51b, a portion 50b' where the second fastening portion 57b is disposed and a portion 50b'' other than the portion 50b' are integrally formed. At this time, the interface between the portion 50b' and the portion 50b'' is composed of a closed portion and an open portion. A communication hole 61b communicating with the untreated gas chamber 31a is perforated on the outer peripheral surface of the portion 50b'' with the sealed portion, and this communication hole 61b is a through hole formed in the arm 59b ( 62b) and the supply hole 63b. On the other hand, the outer peripheral surface of the portion 50b'' with the open portion is closed and communicated back and forth.

The elastic member 80 is supported by the bolt 81 while being interposed between the first fastening part 57a and the second fastening part 57b. The first fastening portion 57a or the second fastening portion 57b is slidably installed with respect to the bolt 81 . In addition, a nut 82 serving as a stopper of the first fastening portion 57a is fastened to the bolt 81 .

The elastic member 80 is interposed between the first fastening part 57a and the second fastening part 57b and supported by the bolt 81, and the first fastening part 57a or the second fastening part 57b is It is provided slidably with respect to the bolt 81. In addition, a nut 82 serving as a stopper of the first fastening portion 57a is fastened to the bolt 81 , and by the configuration of the elastic member 80 , the first distribution rotor 50a and the second distribution After fastening with the nut 82 so that a gap is formed between the rotors 50b, when the first housing 10 is pushed, the elastic member 80 is compressed while the first distribution rotor 50a is pushed. In this compressed state, when the first housing 10 and the second housing 30 are fastened, the distribution rotor 50 is pushed to both sides by the elastic member 80, and the distribution plate 40 and the flange ( 17) and rotates in close contact with it. In addition, a strip 87 is further installed between the first distribution rotor 50a and the second distribution rotor 50b to block the gap between the distribution rotors or to variably apply to the gap between the distribution rotors due to wear during operation. has been

However, in this conventional split-type distribution rotor, the first distribution rotor is in surface contact with the flange of the first housing and the second distribution rotor is in surface contact with the distribution plate of the second housing. A gap and a gap inevitably occur between the first distribution rotor and between the second distribution rotor and the distribution plate, thereby lowering airtightness. There was a problem that caused a decrease in the reliability of the

Registered Patent No. 0524290 (2005.10.26. Announcement) "Separable distribution rotor and rotor distributor adopting this distribution rotor"

Accordingly, the present invention has been devised to solve the problems of the related art as described above, and its purpose is to make the front and rear surfaces of the distribution rotor with respect to the flange of the first housing and the distribution plate of the second housing of a material having excellent heat resistance and durability. By ensuring airtightness by line contact with the packing, the airtightness between the distribution rotor and the flange of the first housing and the distribution plate of the second housing is definitely improved, and maintenance and repair according to the abrasion of the airtight packing and the gap control of the distribution rotor An object of the present invention is to provide a distribution rotor for a rotor distributor of a thermal regenerative oxidation facility so that this can be easily accomplished. Another object of the present invention is to provide a distribution rotor for a rotor distributor of a thermal storage oxidation facility that absorbs an external shock applied to the distribution rotor and absorbs and accommodates deformation of the distribution rotor due to heat with the elastic force of a spring.

One form of a distribution rotor for a rotor distributor of a thermal regenerative oxidation facility according to the present invention for achieving the object of the present invention is to form a rotor body with a cylindrical body, and the inside of the rotor body is radiation centering on the front and rear central shaft holes. The distribution blades are provided at equal intervals on the upper side to form a supply distribution space and a discharge distribution space for supply and discharge on the left and right sides of the neutral portion and the purge portion that are symmetrical to each other. The rotor distributor of the thermal regenerative oxidation facility formed in the rotor body and having a neutral hole and a purge hole partitioned to communicate with the supply distribution space and the discharge distribution space including the neutral part and the purge part in the front and rear one side direction of the rotor body, and a plurality of supply holes and discharge holes In the distribution rotor for

Shaft tube projections A and B are formed on the outer front side of the front and rear central shaft holes of the rotor body, and annular support jaws A and B are formed along the front and rear outer circumferences of the rotor body to form the same surface as the outer surface of the rotor body, , On the outside of the shaft tube projections A and B, an annular first airtight packing is formed to slightly protrude from the shaft tube projections A and B, and the annular second airtight packing is formed on the outside of the annular support jaw portions A and B of the annular It is formed to slightly protrude from the supporting jaws A and B, and the neutral portion between the shaft tube protrusions A and B and the supporting jaws A and B and the front portion of the purge part have the same area so as to form the same plane as the first airtight packing and the second airtight packing. It is characterized in that it is provided with a first surface airtight packing and a second surface airtight packing.

Another form of the distribution rotor for the rotor distributor of the thermal storage oxidation facility according to the present invention is to form the rotor body in a cylindrical body, and the inside of the rotor body is provided with distribution blades at equal intervals on the radiation centering on the front and rear central shaft holes. A supply distribution space and a discharge distribution space for supply and discharge are formed on both left and right sides of the neutral portion and the purge portion symmetrical to each other, and a communication hole communicating with the supply distribution space is formed on a side surface of the rotor body, and front and rear of the rotor body In a distribution rotor for a rotor distributor of a thermal storage oxidation facility in which a neutral hole and a purge hole partitioned to communicate with the supply distribution space and the discharge distribution space including the neutral part and the purge part in one direction, and a plurality of supply holes and discharge holes are formed,

Shaft tube projections A and B are formed on the outer front side of the front and rear central shaft holes of the rotor body, and annular support jaws A and B are formed along the front and rear outer circumferences of the rotor body to form the same surface as the outer surface of the rotor body, , to form a neutral partition wall and a purge partition wall on the boundary of the neutral part and the purge part between the shaft tube projections A and B and the annular support jaws A and B, respectively, and the annular first part on the outside of the shaft tube projections A and B The airtight packing is formed to slightly protrude from the shaft tube projections A and B, and an annular second airtight packing is formed on the outside of the annular supporting jaws A and B to slightly protrude from the annular supporting jaws A and B, and the neutral A plate-shaped third airtight packing is formed on each side of the sub-partition wall and the purge part partition wall to slightly protrude from the neutral part partition wall and the purge part partition wall, but the first air-tight packing, the second gas-tight packing, and the third air-tight packing are It is characterized in that they all have a protruding length to be positioned on the same plane.

In addition, the rotor body is configured to be separated into a first rotor body and a second rotor body, and the first rotor body and the second rotor body are opposite to each other in plurality outside the ends of the first rotor body and the second rotor body, respectively. It is characterized in that the first carbon paper piece and the second carbon paper piece are formed so as to be connected between the first carbon paper piece and the second carbon paper piece by a carbon paper spring, and the second airtight packing has a bolt fastening piece at both ends. It is characterized in that the bolts are fastened to the annular support jaws A and B together with the annular fixing band.

As described above, the present invention forms the shaft tube protrusions A and B on the outer front side of the front and rear central shaft holes of the rotor body, and installs the annular first airtight packing on the outside of the shaft tube projections A and B to slightly protrude, and the rotor body Annular support jaws A and B are formed on the outside of the front and rear ends of the support jaws A and B, and an annular second airtight packing is installed to slightly protrude on the outside of the support jaws A and B, and the shaft tube protrusions A and B and annular support jaws A, Form a first flat airtight packing and a second planar airtight packing in the front part of the neutral part and the purge part between B, or form a partition wall on the boundary of the neutral part and the purge part, and apply a plate-shaped third airtight packing to the partition wall. By protrudingly installed so that airtightness can be achieved by line contact to the flange of the first housing and the distribution plate of the second housing, respectively, the airtightness is excellent, and the gap control is easy to improve the reliability of facilities and devices according to the increase in processing efficiency has the effect of further increasing

In addition, the present invention is a partition wall on the boundary between the shaft pipe projections A and B and the annular support jaws A and B and the neutral portion and the purge portion by fastening the first airtight packing, the second airtight packing, and the third airtight packing by bolts. Each can be easily installed, and in the case of the second airtight packing, bolts can be fastened to the annular support jaws A and B together with an annular fixing band having bolted fastening pieces at both ends. It has the effect of simplicity of maintenance and repair and possible additional installation.

In addition, according to the present invention, the rotor body is configured to be separated into a first rotor body and a second rotor body, and the first rotor body and the second rotor body are opposite to each other in plurality on the outside of each end of the first rotor body and the second rotor body By forming a first carbon paper piece and a second carbon paper piece so as to be able to connect between the first carbon paper piece and the second carbon paper piece with a carbon paper spring, an external shock applied to the distribution rotor is absorbed and the deformation of the distribution rotor due to heat is reduced by the spring. Since it can be absorbed and accommodated by elastic force, it also has the advantage of being able to prevent deformation and damage of the distribution rotor in advance.

1 is an exploded perspective view showing a conventional split-type distribution rotor and a rotor distributor adopting the distribution rotor.
Figure 2 is a perspective view showing the coupled state of Figure 1;
Fig. 3 is a longitudinal sectional view of Fig. 2;
4 and 5 show an embodiment of the present invention,
4 is a perspective view.
Fig. 5 is a rear perspective view of Fig. 4;
6 and 7 show another embodiment of the present invention,
6 is a perspective view.
7 is a rear perspective view of FIG.

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

4 and 5 show an embodiment of the present invention, FIG. 4 is a perspective view, and FIG. 5 is a rear perspective view of FIG. As shown, the present invention constitutes the rotor body 100 in a cylindrical body, and the distribution blades 102 again inside the rotor body 100 are centered on the front and rear central shaft holes 101a and 101b. It is formed at equal intervals on each other, and at this time, the supply distribution space 105 to which untreated gas is supplied and the discharge distribution space to which the treated gas is discharged, centering on the neutral part 103 and the purge part 104, which are symmetrical to each other. (106). In addition, a communication hole 107 communicating with the supply distribution space 105 is formed on the side surface of the rotor body 100 so that the untreated gas introduced into the second housing 30 of FIGS. 1 to 3 passes through the communication hole. To be able to be supplied to the supply distribution space 105 side of the rotor body 100 through the 107 , and the treated gas is discharged from the discharge distribution space 106 through the processing gas discharge duct of the first housing 10 . that made it possible

In the distribution rotor for the rotor distributor of such a thermal storage oxidation facility, a feature of the present invention is that the untreated gas supplied through the supply distribution space 105 of the rotor body 100 and the processed gas discharged through the discharge distribution space 106 are The purpose of the present invention is to further increase the airtightness so as not to mix with each other, and for this purpose, the present invention provides the front and rear central shaft holes 101a and 101b portions, the neutral portion 103 and the purge portion 104 that are the boundary between the untreated gas and the processed gas. ) part and the rotor body 100 is configured to improve the airtightness of the outer part. (See FIGS. 1 to 3 .)

To explain this in more detail, first, the shaft tube projections A, B (112a, 112b) are formed to protrude toward the outer front side of the front and rear central shaft holes 101a, 101b of the rotor body 100, and the shaft tube projection A , B (112a) (112b), the annular first airtight packing 115 corresponding to the outer diameter of the shaft pipe protrusion A, B (112a) (112b) but fitted to the outside of the fixed, the first airtight packing (115) The shaft tube projections A, B (112a) (112b) are fixed to protrude somewhat, and the fixing of the first airtight packing 115 to the shaft tube projections A, B (112a) (112b) is made by fastening the bolts.

Then, along the outer periphery of the front and rear ends of the rotor body 100, annular support jaws A, B (113a, 113b) forming the same surface as the outer surface of the rotor body 100 are formed, and the support jaws A, The annular second airtight packing 116 corresponding to the outer diameter of the supporting jaws A, B (113a, 113b) is fitted to the outside of the B (113a) (113b) and fixed, but the second airtight packing 116 is It is fixed to protrude slightly from the supporting jaws A, B (113a) (113b), and the fixing of the second airtight packing 116 to the supporting jaws A, B (113a, 113b) is bolted at both ends together with bolting. It is made by an annular fixing band 118 having 118a. The annular fixing band 118 has long holes 118b formed at intervals along the circumference, so that the second airtight packing 116 through the long holes 118b is attached to the support jaws A and B (113a) of the rotor body 100. ) (113b), the long hole (118b) wraps the fixing band 118 on the second airtight packing 116, and bolts the bolt fastening pieces 118a on both ends of the fixing band 118. When the fixing band 118 is pulled toward the bolt fastening piece 118a and tightened by the tightening force generated when connecting and tightening, the movement of the fixing band 118 is accommodated.

In addition, the neutral portion 103 between the shaft protrusions A, B (112a, 112b) and the annular supporting jaw portions A, B (113a, 113b) and the front portion of the purge portion 104 have the same area as the first As having a planar airtight packing 122 and a second facet airtight packing 123, in the end, the first airtight packing 115 and the second airtight packing 116, the first facet airtight packing 122 and the second Both the two-sided airtight packing 123 has a protruding length so that line contact and surface contact can be made together on the same surface. Accordingly, the first airtight packing 115 installed on the outside of the shaft tube projections A, B (112a, 112b) of the rotor body 100 and the annular support jaws A, B (113a) (113b) of the rotor body 100 A second airtight packing 116 installed at the outer end and a neutral portion 103 and a purge portion 104 between the shaft tube protrusions A, B (112a, 112b) and the annular support jaws A, B (113a, 113b) ) of the first planar airtight packing 122 and the second planar airtight packing 123 provided on the front part of the distribution plate 40 of the second housing and the flange 17 of the first housing 10 are in line contact By allowing the airtightness between them to be made in a state of being, the airtightness is excellent as well as the first airtight packing 115 and the second airtight packing 116, the first airtight packing 122 and the second airtight packing 123 ), maintenance is easy, additional installation of airtight packing is possible, and it has the advantage of easy adjustment of the gap of the rotor body 100. (See Figs. 1 to 3.)

6 and 7 are views showing another embodiment of the present invention, FIG. 6 is a perspective view, and FIG. 7 is a rear perspective view of FIG. As shown, the present invention constitutes the rotor body 100 in a cylindrical body, and the distribution blades 102 again inside the rotor body 100 are centered on the front and rear central shaft holes 101a and 101b. The phase is formed at equal intervals, and at this time, the supply distribution space 105 to which untreated gas is supplied and the discharge distribution space to which the treated gas is discharged, centering on the neutral part 103 and the purge part 104, which are symmetrical to each other. (106). In addition, a communication hole 107 communicating with the supply distribution space 105 is formed on the side surface of the rotor body 100 so that the untreated gas introduced into the second housing 30 of FIGS. 1 to 3 passes through the communication hole. To be able to be supplied to the supply distribution space 105 side of the rotor body 100 through the 107 , and the treated gas is discharged from the discharge distribution space 106 through the processing gas discharge duct of the first housing 10 . that made it possible To this end, a neutral hole 108 partitioned in communication with the supply distribution space 105 and the discharge distribution space 106 including the neutral portion 103 and the purge portion 104 in the front and rear one direction of the rotor body 100 . ), a purge hole 109, and a plurality of supply holes 110 and discharge holes 111 are formed.

In the distribution rotor for the rotor distributor of such a thermal storage oxidation facility, a feature of the present invention is that the untreated gas supplied through the supply distribution space 105 of the rotor body 100 and the processed gas discharged through the discharge distribution space 106 are The purpose of the present invention is to further increase the airtightness so as not to mix with each other, and for this purpose, the present invention provides the front and rear central shaft holes 101a and 101b portions, the neutral portion 103 and the purge portion 104 that are the boundary between the untreated gas and the processed gas. ) and the outer part of the rotor body 100 are configured to be in line contact with the flange 17 of the first housing 10 and the distribution plate 40 of the second housing. (See FIGS. 1 to 3 .)

If this will be described in more detail with reference to the accompanying Figures 6 and 7, first, the shaft tube protrusions A and B (112a) to protrude toward the outer front side of the front and rear central shaft holes 101a and 101b of the rotor body 100. (112b) is formed, and the first airtight packing 115 of an annular shape corresponding to the outer diameter of the shaft tube projections A, B (112a) (112b) is fitted on the outside of the shaft tube projections A, B (112a) (112b) However, the first airtight packing 115 is fixed to protrude slightly from the shaft tube projections A, B (112a) (112b), and the first hermetic packing 115 for the shaft tube projections A, B (112a) (112b). is fixed by fastening bolts.

Then, along the outer periphery of the front and rear ends of the rotor body 100, annular support jaws A, B (113a, 113b) forming the same surface as the outer surface of the rotor body 100 are formed, and the support jaws A, The annular second airtight packing 116 corresponding to the outer diameter of the supporting jaws A, B (113a, 113b) is fitted to the outside of the B (113a) (113b) and fixed, but the second airtight packing 116 is It is fixed to protrude slightly from the supporting jaws A, B (113a) (113b), and the fixing of the second airtight packing 116 to the supporting jaws A, B (113a, 113b) is bolted at both ends together with bolting. It is made by an annular fixing band 118 having 118a. The annular fixing band 118 has long holes 118b formed at intervals along the circumference, so that the second airtight packing 116 through the long holes 118b is attached to the support jaws A and B (113a) of the rotor body 100. ) (113b), the long hole (118b) wraps the fixing band 118 on the second airtight packing 116, and bolts the bolt fastening pieces 118a on both ends of the fixing band 118. When the fixing band 118 is pulled toward the bolt fastening piece 118a and tightened by the tightening force generated when connecting and tightening, the movement of the fixing band 118 is accommodated.

In addition, partition walls 114 on the boundary of the neutral portion 103 and the purge portion 104 between the shaft protrusions A, B (112a, 112b) and the annular support jaws A, B (113a, 113b), respectively. ) is formed, and the third airtight packing 117 in plate shape is fixed to each of the partition walls 114 , but is formed to slightly protrude from the partition wall 114 . As a result, the first airtight packing 115, the second airtight packing 116, and the third airtight packing 117 all have a protruding length so that they can be brought into line contact together on the same surface.

Therefore, the present invention is the first airtight packing 115 installed on the outside of the shaft tube projections A, B (112a, 112b) of the rotor body 100 and the annular support jaws A, B (113a) of the rotor body 100 A second airtight packing 116 installed at the outer end of (113b) and a neutral portion 103 between the shaft tube protrusions A, B (112a) (112b) and the annular support jaws A, B (113a) (113b) and The third airtight packing 117 installed on the partition wall 114 formed on the boundary of the purge part 104, respectively, is in line contact with the distribution plate 40 of the second housing and the flange 17 of the first housing 10 By allowing the airtightness between them to be made in an airtight state, not only the airtightness is excellent, but also maintenance is easy when the first airtight packing 115, the second airtight packing 116, and the third airtight packing 117 are worn. , it is also possible to additionally install an airtight packing, and has the advantage of easy adjustment of the gap of the rotor body 100. (See Figs. 1 to 3.)

Meanwhile, in the present invention, the rotor body 100 is divided into a first rotor body 100a and a second rotor body 100b to accommodate the expansion of the rotor body 100 due to thermal deformation and to absorb external shock. Separately, the first rotor body 100a and the second rotor body 100b were connected to each other by a tanji spring 121 . To explain this in more detail, a plurality of first and second elastic pieces 119 and 120 are integrally opposed to each other on the outside of each end of the first rotor body 100a and the second rotor body 100b. The tanji spring 121 is connected between the first tanji piece 119 and the second tanji piece 120. Therefore, when the rotor body 100 is expanded due to thermal deformation, the displacement of the rotor body 100 can be accommodated by the tangential spring 121, and external shock can also be absorbed, so the rotor body 100. It is possible to prevent deformation or damage of

As such, the present invention forms the shaft tube projections A and B toward the outer front side of the front and rear central shaft holes of the rotor body, and installs the annular first airtight packing to slightly protrude on the outside of the shaft tube projections A and B, and the front and rear ends of the rotor body Annular support jaws A and B are formed on the outside, and annular second airtight packing is installed to slightly protrude on the outside of the support jaws A and B, and between the shaft tube protrusions A and B and the annular support jaws A and B Forming the first planar airtight packing 122 and the second planar airtight packing 123 on the front part of the neutral part and the purge part, or forming a partition wall on the boundary of the neutral part and the purge part, to form a third airtight seal in the plate shape on the partition wall By installing the packing to protrude slightly, airtightness can be achieved by line contact and surface contact to the flange of the first housing and the distribution plate of the second housing, respectively. Accordingly, it is possible to further increase the reliability of the equipment and apparatus.

In addition, the present invention is a partition wall on the boundary between the shaft pipe projections A and B and the annular support jaws A and B and the neutral portion and the purge portion by fastening the first airtight packing, the second airtight packing, and the third airtight packing by bolts. Each can be easily installed, and in the case of the second airtight packing, bolts can be fastened to the annular support jaws A and B together with annular fixing bands having bolted fastening pieces at both ends. Simple maintenance and repair and additional installation are possible.

In addition, according to the present invention, the rotor body is configured to be separated into a first rotor body and a second rotor body, and the first rotor body and the second rotor body are opposite to each other in plurality on the outside of each end of the first rotor body and the second rotor body By forming a first carbon paper piece and a second carbon paper piece so as to be able to connect between the first carbon paper piece and the second carbon paper piece with a carbon paper spring, an external shock applied to the distribution rotor is absorbed and the deformation of the distribution rotor due to heat is reduced by the spring. It can be absorbed and accommodated by elastic force, so that deformation and damage of the distribution rotor can be prevented in advance.

In the above, the distribution rotor for the rotor distributor of the regenerative oxidation facility according to the present invention has been described in detail, but this is only a description of the most preferred embodiment of the present invention, and the present invention is not limited thereto. The scope is determined and limited by In addition, it will be clear that any person skilled in the art will be able to make various modifications and imitations according to the description of the specification of the present invention, but this also does not depart from the scope of the present invention.

100: rotor body 100a, 100b: first and second rotor body
101a, 101b: front and rear central shaft hole 102: distribution wings
103: neutral part 104: purge part
105: supply distribution space 106: discharge distribution space
107: through hole 108: neutral hole
109: purge hole 110: supply hole
111: discharge hole 112a, 112b: shaft protrusion A, B
113a, 113b: support jaw 114: partition wall
115: first airtight packing 116: second airtight packing
117: third airtight packing 118: fixed band
118a: bolted piece 118b: long hole
119,120: first and second tanji part 121: tanji spring
122,123: first and second surface airtight packing

Claims (4)

The rotor body 100 is formed in a cylindrical body, and the inside of the rotor body 100 is provided with distribution wings 102 at equal intervals on the radiation centering on the front and rear central shaft holes 101a and 101b to achieve symmetry with each other. A supply distribution space 105 and a discharge distribution space 106 for supply and discharge are formed on the left and right sides of the neutral portion 103 and the purge portion 104 forming a communication hole communicating with the supply distribution space 105 . 107 is formed on the side surface of the rotor body 100, the supply distribution space 105 and the discharge distribution space including the neutral portion 103 and the purge portion 104 in the front and rear one side direction of the rotor body 100 In the distribution rotor for a rotor distributor of a thermal storage oxidation facility in which a neutral hole 108 and a purge hole 109 partitioned to communicate with (106), and a plurality of supply holes 110 and discharge holes 111 are formed,
Shaft tube projections A, B (112a, 112b) are formed on the outer front side of the front and rear central shaft holes 101a and 101b of the rotor body 100, and the rotor body 100 along the front and rear outer circumferences Forming annular support jaws A, B (113a, 113b) forming the same plane as the outer surface of the body 100, the annular first airtight packing ( 115) is formed to slightly protrude from the shaft tube protrusions A, B (112a) (112b), and an annular second airtight packing 116 is formed on the outside of the annular supporting jaws A, B (113a, 113b). Formed to slightly protrude from the supporting jaws A, B (113a) (113b) of the shaft tube protrusion A, B (112a) (112b) and the first surface airtight packing 122 and the second surface airtight packing 123 in the same area on the front part of the neutral part 103 and the purge part 104 between the supporting jaws A, B (113a, 113b). to provide
The rotor body 100 is configured to be separated into a first rotor body 100a and a second rotor body 100b, and the first rotor body 100a and the second rotor body 100b include a first rotor body ( 100a) and the second rotor body 100b to form a plurality of first carbonization pieces 119 and second carbonization pieces 120 opposite to each other on the outside of each end, the first carbonization pieces 119 and the second Connecting between the tanji pieces 120 with a tanji spring 121,
The second airtight packing 116 is bolted to the annular support jaws A, B (113a, 113b) together with an annular fixing band 118 having bolt fastening pieces 118a at both ends. A distribution rotor for a rotor distributor of a regenerative oxidation facility.
The rotor body 100 is formed in a cylindrical body, and the inside of the rotor body 100 is provided with distribution wings 102 at equal intervals on the radiation centering on the front and rear central shaft holes 101a and 101b to achieve symmetry with each other. A supply distribution space 105 and a discharge distribution space 106 for supply and discharge are formed on the left and right sides of the neutral portion 103 and the purge portion 104 forming a communication hole communicating with the supply distribution space 105 . 107 is formed on the side surface of the rotor body 100, the supply distribution space 105 and the discharge distribution space including the neutral portion 103 and the purge portion 104 in the front and rear one side direction of the rotor body 100 In the distribution rotor for a rotor distributor of a thermal storage oxidation facility in which a neutral hole 108 and a purge hole 109 partitioned to communicate with (106), and a plurality of supply holes 110 and discharge holes 111 are formed,
Shaft tube projections A, B (112a, 112b) are formed on the outer front side of the front and rear central shaft holes 101a and 101b of the rotor body 100, and the rotor body 100 along the front and rear outer circumferences Annular support jaws A, B (113a, 113b) that form the same plane as the outer surface of the body 100 are formed, and the shaft protrusions A, B (112a) (112b) and annular support jaws A, B (113a) are formed. ) (113b) to form a partition wall 114 on the boundary between the neutral part 103 and the purge part 104, respectively, and the annular first The airtight packing 115 is formed to slightly protrude from the shaft tube protrusions A, B (112a) (112b), and the annular second airtight packing 116 is formed on the outside of the annular support jaws A, B (113a, 113b). is formed to slightly protrude from the annular support jaws A, B (113a, 113b), and a plate-shaped third airtight packing 117 is formed on each side of the partition wall 114 slightly from the partition wall 114. But formed to protrude, the first airtight packing 115, the second airtight packing 116, and the third airtight packing 117 have a protruding length to be located on the same surface,
The rotor body 100 is configured to be separated into a first rotor body 100a and a second rotor body 100b, and the first rotor body 100a and the second rotor body 100b include a first rotor body ( 100a) and the second rotor body 100b to form a plurality of first carbonization pieces 119 and second carbonization pieces 120 opposite to each other on the outside of each end, the first carbonization pieces 119 and the second Connecting between the tanji pieces 120 with a tanji spring 121,
The second airtight packing 116 is bolted to the annular support jaws A, B (113a, 113b) together with an annular fixing band 118 having bolt fastening pieces 118a at both ends. A distribution rotor for a rotor distributor of a regenerative oxidation facility. delete delete

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