KR20210020859A - Marine SCR system reactor conduction device - Google Patents

Abstract

The present invention discloses a marine SCR system reactor conduction device, the device is mounted in the expansion cavity of the square connection round of the reactor inlet, and includes an inner conduction cylinder in the shape of a hollow truncated cone, and a plurality of groups on the outer conical surface of the internal conduction cylinder Internal splitter plates distributed in an annular array are installed, the internal conduction cylinders are integrally molded with multiple groups of internal splitter plates, all of the multiple groups of internal splitter plates are stepped, and the internal conduction cylinders on the multiple groups of internal splitter plates The inlet conduction ring, the middle conduction ring, and the outlet conduction ring, which are installed coaxially with each other, are fixed and installed. Since the side of the inner conduction cylinder of the present invention and the side of the conduction ring with a gap in the middle form a multi-layered curved structure with a coaxial conical surface, it is possible to improve the radial non-uniformity of the airflow and spread the waste gas airflow radially evenly, The entrance/exit splitter plate and the inner splitter plate divide the multi-layered curved structure into a plurality of equal area regions in the circumferential direction, thereby improving non-uniformity due to mutual interference of axial air flows.

Description

Marine SCR system reactor conduction device

The present invention pertains to the technical field of reactor ducting device, and more particularly, to a reactor ducting device for a marine SCR system.

Selective Catalytic Reduction (SCR) technology is the mainstream technology for post-treatment of NOx emissions from marine diesel engines, and two important indicators measuring the performance of SCR denitrification systems are denitrification efficiency and NH ₃ escape rate. These two indicators are collectively influenced by a number of factors, one of which is the uniformity of the outlet velocity of the gas mixture entering the catalyst bed of the SCR reactor from the expansion cavity. Without a gas-conducting device, the gas mixture goes through the process of increasing from a small tube diameter, at which time the velocities of different positions change. If the flow rate at which the waste gas enters the catalyst pore channel is non-uniform, some waste gas may be discharged without reacting in an excessively fast area, and in an excessively slow area, the catalytic capacity cannot be fully utilized and the reactor performance is degraded. It can be degraded. Therefore, the gas conduction device in the expansion cavity of the front section of the reactor is very important, and has a direct influence on the denitration efficiency and the service life of the catalyst.

It is an object of the present invention to provide a vessel SCR system reactor conduction device, so that the outlet flow rate is uniform, the pressure loss is low, and the normal operation of the SCR system is ensured, while the mixed gas is mixed at different positions while passing through the increasingly larger pipe diameter. It is to effectively solve the problem that the flow rate of the waste gas into the catalyst pore channel is uneven by allowing the gas to enter the catalyst bed of the reactor at the same speed.

The present invention provides a marine SCR system reactor conduction device, the device being mounted in the expansion cavity of the reactor inlet square connection round, and comprising an inner conduction cylinder in the shape of a hollow truncated cone, and a plurality of groups on the outer conical surface of the inner conduction cylinder Internal dividers distributed in an annular array are installed, and the internal conduction cylinder is integrally molded with a plurality of groups of internal dividers, and the plurality of groups of the internal dividers are all stepped, and internal conduction on the plurality of groups of internal dividers An inlet conduction ring, an intermediate conduction ring, and an outlet conduction ring installed coaxially with the cylinder are fixed and installed, and the intermediate conduction ring has a predetermined gap between the inlet conduction ring and the outlet conduction ring, respectively, and the side of the inlet conduction ring A plurality of groups of inlet splitter plates corresponding to the position of the internal splitter plate are installed in the inlet splitter plate, and the inlet splitter plates are distributed on the side of the inlet conduction ring in an annular array, and the inlet splitter plate is integrally formed with the inlet conduction ring, and the outlet conduction plate On the side of the ring, a plurality of groups of outlet splitter plates corresponding to the position of the internal splitter plate are installed, the outlet splitter plates are distributed on the side of the outlet conduction ring in an annular array, and the outlet divider plate is integrally formed with the outlet conduction ring.

Further, the space between the outer conical surface of the inner conduction cylinder and the inlet conduction ring, the middle conduction ring, and the outlet conduction ring is divided into a plurality of groups of first areas having the same volume by a plurality of groups of internal splitter plates, and the reactor inlet The space between the inner wall of the expansion cavity of the square connecting round and the inlet conduit ring, the middle conduit ring, and the outlet conduit ring is divided into a second area of the same volume by a plurality of groups of inlet and outlet dividers, and the interior The cavity of the conduction cylinder is a third area, the inlet and outlet area ratio of any one of the first areas of the plurality of groups, the inlet and outlet area ratio of any one of the second areas of the plurality of groups, and the inlet and outlet of the third area The area ratios are all the same, and the area of any one of the first regions of the plurality of groups perpendicular to the inner conduction cylinder axis plane, the area of any one of the second regions of the plurality of groups, and the third All of the areas have the same area. The inlet and outlet dividing plate and the inner dividing plate divide the reactor inlet square connection round expansion cavity into a plurality of equal areas in the circumferential direction, and the constant velocity mixed gas is divided into a first area, a second area, and a third area having the same inlet and outlet area ratio. By entering, it is ensured that the waste gas entering the square reactor has a uniform constant velocity.

Further, the inlet conduit ring and the outlet conduit ring are respectively located at both ends of the inner splitter plate, and the number of intermediate conduit rings between the inlet conduit ring and the outlet conduit ring is one or more. The number of intermediate conduction rings depends on the size of the conduction device.

Furthermore, there is a certain gap between adjacent intermediate conduction rings of the plurality of intermediate conduction rings.

Furthermore, the sizes of the inlet conduit ring, the middle conduit ring, and the outlet conduit ring are sequentially and gradually increased, and the inlet conduit ring, the intermediate conduit ring, and the outlet conduit ring have a conical curved structure. Conical curved surface structure, coaxial arrangement effectively reduces airflow resistance and reduces pressure loss. Both the side of the inner conduction cylinder and the side of the conduction ring with a gap in the middle are coaxial conical surfaces, and form a multi-layered curved structure to reduce the disturbance of the waste gas airflow and improve the radial non-uniformity of the airflow.

Furthermore, the size of the inlet splitter plate is larger than the size of the outlet splitter plate.

Further, the plurality of groups of the inner splitter plates are installed perpendicular to the outer conical surface of the inner conduction cylinder, the plurality of groups of inlet splitter plates are installed perpendicular to the side of the inlet conduction ring, and the plurality of groups of outlet splitter plates are installed at the outlet. It is installed vertically on the side of the conduction ring. The entrance/exit splitter plate and the inner splitter plate divide the multi-layered curved structure into a plurality of equal area regions in the circumferential direction, reduce mutual disturbance of airflow in the circumferential direction, and improve the circumferential direction non-uniformity of the waste gas airflow.

Further, the inlet splitter plate and the inner splitter plate corresponding to each other are positioned on the same plane, and the outlet splitter plate and the inner splitter plate corresponding to each other are positioned on the same plane.

Further, a plurality of groups of the inlet dividers and a plurality of groups of outlet dividers are all installed in parallel in a one-to-one correspondence.

Further, the plurality of groups of the inlet splitter plates and the plurality of groups of outlet splitter plates are all welded to the inner wall of the expansion cavity of the reactor inlet square connection round.

Advantageous effects of the present invention are as follows. That is, in the present invention, all of the inlet conduction ring, the middle conduction ring, and the outlet conduction ring have a conical curved structure and are coaxially arranged to effectively lower airflow resistance and reduce pressure loss. The side of the inner conduction cylinder and the side of the conduction ring having a gap in the middle are all coaxial conical surfaces, and form a multi-layered curved structure to reduce the disturbance of the waste gas airflow and improve the radial non-uniformity of the airflow. Both the entrance/exit splitter plate and the inner splitter plate divide a multi-layered curved structure into a plurality of equal-area regions in the circumferential direction, reduce mutual disturbance of airflow in the circumferential direction, and improve the circumferential direction non-uniformity of the waste gas airflow. The constant velocity mixed gas enters the first region, the second region, and the third region, respectively, having the same inlet and outlet area ratio, and ensures that the waste gas entering the square reactor has a uniform constant velocity.

1 is a structural diagram of the present invention.
2 is an axial schematic diagram of the present invention.
3 is a cross-sectional view of the present invention.
4 is a front view of FIG. 3.
5 is a structural diagram of an internal splitter plate.
6 is a plan view of the present invention.
7 is a bottom view of the present invention.
Figure 8 is a schematic diagram of the present invention installed in a reactor inlet square connection round.

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

1 and 2, the present invention is a marine SCR system reactor conduction device, the device is installed in the expansion cavity of the reactor inlet square connection round 11, the size of each member of the device is the reactor inlet square It should be made to fit the size of the expansion cavity of the connecting round 11, so that the convection device ensures that the waste gas outlet flow rate uniformly enters the catalyst bed for different standard reactors. Here, the device includes an inner conduction cylinder 1 in the shape of a hollow truncated cone, and an inner splitter plate 2 distributed in a plurality of groups of annular arrays is installed on the outer conical surface of the inner conduction cylinder 1, and the inner conduction The cylinder (1) is integrally molded with a plurality of groups of inner splitter plates (2), and the plurality of groups of inner splitter plates (2) are all installed perpendicular to the outer conical surface of the inner conduction cylinder (1), and The splitter plates 2 are all stepped, and on the plurality of groups of the inner splitter plates 2, the inlet conduction ring 3, the intermediate conduction ring 4 and the outlet conduction ring 5 installed coaxially with the internal conduction cylinder 1 ) Is fixed and installed, and the sizes of the inlet conduit ring (3), the intermediate conduit ring (4) and the outlet conduit ring (5) are gradually increased in sequence, and the inlet conduit ring (3), the intermediate conduit ring (4) And the outlet conduction ring 5 are both conical curved structure, and the conical curved structure and coaxial arrangement effectively lower the airflow resistance and reduce the pressure loss.

3 to 5, the inlet conduction ring 3 and the outlet conduction ring 5 are located at both ends of the inner splitter plate 2, respectively, and the intermediate conduction ring 4 is an inlet conduction ring 3, respectively. ) And the outlet conduction ring (5), the number of intermediate conduction rings (4) between the inlet conduction ring (3) and the outlet conduction ring (5) is one or more, and the specific The quantity depends on the size of the conduction device, and when there are a plurality of intermediate conduction rings 4, a certain gap exists between adjacent intermediate conduction rings 4 among the plurality of intermediate conduction rings 4. In this embodiment, the number of intermediate conduction rings 4 is one, wherein the inlet conduction ring 3, the intermediate conduction ring 4 and the outlet conduction ring 4 having a gap between the sides and the middle of the inner conduction cylinder 1 The sides of (5) are all coaxial conical surfaces, and by forming a multi-layered curved structure, the disturbance of the waste gas airflow can be reduced and the radial non-uniformity of the airflow can be improved.

A plurality of groups of inlet splitter plates 6 corresponding to the position of the inner splitter plate 2 are installed on the side of the inlet conduction ring 3, and the plurality of groups of inlet splitter plates 6 are located on the side of the inlet conduction ring 3 Vertically installed, and a plurality of groups of inlet splitter plates 6 are distributed on the side of the inlet conduction ring 3 in an annular array, and the inlet splitter plate 6 and the inlet conduction ring 3 are integrally molded, The inlet divider plate 6 is located on the same plane as the inner divider plate 2 corresponding to each other, and a plurality of groups of outlet divider plates 7 corresponding to the position of the inner divider plate 2 on the side of the outlet conduction ring 5 Is installed, and a plurality of groups of outlet splitter plates 7 are vertically installed on the side of the outlet conduction ring 5, and the plurality of groups of outlet splitter plates 7 are annular arrays and the side of the outlet conduction ring 5 And the outlet divider plate 7 is integrally molded with the outlet conduction ring 5, the outlet divider plate 7 and the inner divider plate 2 corresponding to each other are located in the same plane, where the inlet divider plate ( The size of 6) is larger than the size of the outlet splitter plate 7, and the plurality of groups of inlet splitter plates 6 correspond to the plurality of groups of outlet splitter plates 7 on a one-to-one basis and are installed in parallel. The entrance/exit splitter plate and the inner splitter plate 2 divide the multi-layered curved structure into a plurality of equal area regions in the circumferential direction, thereby reducing mutual disturbance of airflow in the circumferential direction and improving the circumferential direction non-uniformity of the waste gas.

6 and 7, the space between the outer conical surface of the inner conduction cylinder 1 and the inlet conduction ring 3, the intermediate conduction ring 4 and the outlet conduction ring 5 is divided into a plurality of groups A plurality of groups of volumes are divided by a plate (2) into a first region (8) having the same volume, and the inner wall of the expansion cavity of the reactor inlet square connection round (11) and the inlet conduction ring (3), the middle conduction ring (4) and the outlet The space between the conduction rings (5) is divided into a second area (9) having the same volume of a plurality of groups by a plurality of groups of inlet splitter plates (6) and outlet splitter plates (7), and multiple groups of inlet splitter plates ( 6) and the plurality of groups of outlet splitter plates 7 are both welded to the inner wall of the expansion cavity of the reactor inlet square connecting round 11, and the cavity of the inner conduction cylinder 1 is the third area 10, and the plurality of groups The entrance/exit area ratio of the first region 8 of the first region 8, the entrance/exit area ratio of the second region 9 of the plurality of groups of the second region 9, and the third region 10 The inlet and outlet area ratios are all the same, and the area of the first area 8 of the plurality of groups of first areas 8 perpendicular to the axial plane of the inner conduction cylinder 1, the area of the second area of the plurality of groups 9 The area of the second area 9 and the area of the third area 10 are the same. The inlet/outlet splitter plate and the inner splitter plate (2) divide the expansion cavity of the reactor inlet square connection round (11) into a plurality of equal areas in the circumferential direction, and the constant velocity mixed gas is a first area (8) having the same inlet and outlet area ratio, respectively. , It is ensured that the waste gas entering the second region 9 and the third region 10 and entering the square reactor has a uniform constant velocity.

The principle of operation shown in FIG. 8 is as follows. The main thrust of a specific ship is a low-speed diesel engine with a rated output of 13200kW and a rated rotational speed of 111r/min. Here, the expansion cavity inlet of the reactor inlet square connection round 11 is connected to the mixing pipeline through the flange and square connection round section 13 and the DN700 flange 12 of Φ720, and the reactor inlet square connection round 11 The outlet is 1376×1348 in size and connected to the reactor square inlet, and the expansion ratio is about 4.56. The waste gas airflow of the diesel engine enters the expansion cavity of the reactor inlet square connection round 11 from the flange 12 and the flange and square connection round section 13, and if this device is not present, the gas is a process that increases from a small pipe diameter. It is the same as passing through, and at this time, the speed at different locations is different, and the performance of the reactor is degraded.

The device ensures that the gas mixture at different locations can enter the catalyst bed of the reactor at the same speed even when the tube diameter increases, and the inner conduction cylinder 1, the inlet conduction ring 3, and the intermediate conduction ring ( 4) and the outlet conduction ring (5) are welded to the coaxial position through the inner splitter plate (2), and then the reactor inlet square connection round (11) again using the inlet splitter plate (6) and the outlet splitter plate (7). Welded connection to the inner wall of the expansion cavity, and the sides of the inner conduction cylinder (1) and the sides of the inlet conduction ring (3), the intermediate conduction ring (4) and the outlet conduction ring (5) with a gap in the middle are all coaxial conical faces. Therefore, it forms a multi-layered curved structure. That is, by dividing the expansion cavity radially to form a multi-layered curved structure, the disturbance of the waste gas airflow is reduced and the radial non-uniformity of the airflow is improved. In addition, the internal splitter plate 2, the inlet splitter plate 6, and the outlet splitter plate 7 divide the multi-layered curved structure into a plurality of iso-area areas in the circumferential direction, thereby reducing mutual disturbance of airflow in the circumferential direction and reducing waste gas airflow. Improves circumferential uniformity. In addition, the constant velocity mixed gas enters the first region 8, the second region 9 and the third region 10, respectively, having the same inlet and outlet area ratio, and the waste gas entering the square reactor has a uniform constant velocity. Ensure to have. By dividing one large square connection round into a plurality of small isometric areas and expanding it into multiple stages, the airflow is divided into several strands to ensure that gases do not interfere with each other in the diffusion process, and enter the reactor catalyst bed at a uniform rate. To perform a catalytic reduction reaction.

Claims (10)

In the marine SCR system reactor conduction device,
The apparatus is mounted in the expansion cavity of the reactor inlet square connection round, and includes an inner conduction cylinder in the shape of a hollow truncated cone, and an inner splitter plate distributed in a plurality of groups of annular arrays is installed on the outer conical surface of the inner conduction cylinder, and the inner The conduction cylinder is integrally formed with a plurality of groups of internal dividers, and the plurality of groups of the internal dividers are all stepped, and on the plurality of groups of internal dividers, an inlet conduction ring and an intermediate conduction ring are installed coaxially with the internal conduction cylinder. And the outlet conduction ring is fixed and installed, and the intermediate conduction ring has a certain gap between the inlet conduction ring and the outlet conduction ring, respectively, and a plurality of groups of inlet classifications corresponding to the position of the internal divider plate on the side of the inlet conduction ring A plate is installed, the inlet splitter plate is distributed on the side of the inlet conduction ring in an annular array, the inlet splitter plate is integrally formed with the inlet conduction ring, and a plurality of groups corresponding to the position of the inner divider plate on the side of the outlet conduction ring The outlet splitter plate is installed, the outlet splitter plate is distributed on the side of the outlet conduction ring in an annular array, and the outlet divider plate is integrally formed with the outlet conduction ring. The method of claim 1,
The space between the outer conical surface of the inner conduction cylinder and the inlet conduction ring, the middle conduction ring, and the outlet conduction ring is divided into first regions having the same volume of the plurality of groups by the plurality of groups of internal dividers; The space between the inner wall of the expansion cavity of the reactor inlet square connection round and the inlet conduit ring, the middle conduit ring, and the outlet conduit ring is divided into a second area having the same volume of a plurality of groups by a plurality of groups of inlet splitter plates and outlet splitter plates. ; The cavity of the inner conduction cylinder is a third area; The inlet and outlet area ratio of any one of the first areas in the plurality of groups, the inlet area ratio of the second area in the second area of the plurality of groups, and the inlet and outlet area ratio of the third area are all the same, and the internal conduction cylinder axis An area of a first area of a plurality of groups of the first areas perpendicular to the plane, an area of a second area of any of the second areas of the plurality of groups, and an area of the third area are all the same Marine SCR system reactor conduction device. The method of claim 1,
The inlet conduction ring and the outlet conduction ring are respectively located at both ends of the internal splitter plate, and the number of intermediate conduction rings between the inlet conduction ring and the outlet conduction ring is one or more. The method of claim 3,
Marine SCR system reactor conduction apparatus, characterized in that there is a certain gap between adjacent intermediate conduction rings among the plurality of intermediate conduction rings. The method of claim 1,
The sizes of the inlet conduction ring, the intermediate conduction ring, and the outlet conduction ring are sequentially gradually increased, and the inlet conduction ring, the intermediate conduction ring and the outlet conduction ring have a conical curved structure. The method of claim 1,
The vessel SCR system reactor conduction device, characterized in that the size of the inlet splitter plate is larger than the size of the outlet splitter plate. The method of claim 1,
The plurality of groups of the inner splitter plates are installed perpendicular to the outer conical surface of the inner conduction cylinder, the plurality of groups of inlet splitter plates are installed perpendicular to the side of the inlet conduction ring, and the plurality of groups of outlet splitter plates are of the outlet conduction ring. Marine SCR system reactor conduction device, characterized in that installed vertically on the side. The method of claim 7,
The inlet splitter plate and the internal splitter plate corresponding to each other are positioned on the same plane, and the outlet splitter plate and the inner splitter plate corresponding to each other are positioned on the same plane. The method of claim 7,
A vessel SCR system reactor conduction device, characterized in that a plurality of groups of the inlet splitter plates and the plurality of groups of outlet splitter plates are installed in parallel in a one-to-one correspondence. The method of claim 2,
The plurality of groups of the inlet splitter plate and the plurality of groups of outlet splitter plates are all welded to the inner wall of the expansion cavity of the reactor inlet square connection round.

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