DE202017104751U1 - Clamping system for reactor honeycombs - Google Patents

Abstract

A Selective Catalytic Reduction Reactor Chucking System, SCR, comprising a plurality of square honeycombs arranged on a base plate in rows in front of a housing wall, the chucking system comprising: a plurality of chucks disposed respectively on the housing wall midway between two rows are hung by honeycomb; wherein with the clamping bars each lying on both sides under the clamping bars honeycomb in the direction grid can be clamped so that a closed state of the system is achieved; a transverse to the clamping beam, connected to the clamping beam traverse, which is movable so that the clamping bars can simultaneously reach the closed state and leave again; wherein the cross member is lockable at least in the closed state; characterized in that in the side surface of the clamping bar, which points away from the traverse, in the longitudinal direction in each case at least one guide groove is incorporated; and in the at least one guide groove in the longitudinal direction in each case a flexible clamping element is guided, which protrudes in the transverse direction in each case from the guide groove.

Description

The present invention relates to a clamping system for reactor honeycombs, which are used in particular in the exhaust gas filtering of large diesel engines in ships or stationary equipment.

In order to meet the emission regulations of large diesel engines, reactors for selective catalytic reduction, hereinafter referred to as SCR reactor, are used in maritime and stationary applications. In this case, for example, honeycomb with an end face of about 200 to 300 mm square and a length of about 500 to 800 mm placed on a grid and braced from the opposite side, usually with the help of clamping bars. It forms a block of honeycomb. The number of honeycombs is adapted to the amount and concentration of the exhaust gas. The honeycombs include suitable filter substrates which are held in sheet metal shells, for example. The exhaust gas to be filtered flows through the honeycomb block in the longitudinal direction of the honeycomb, so for example from the grid.

In 1 are schematically several rod-shaped reactor honeycomb 1 shown with square cross section. These are arranged in several rows next to each other. Just for the sake of clarity are in 1 shown sixteen honeycombs, which are arranged square.

In 2 are the honeycombs out 1 on a base plate 7 standing arranged. The base plate 7 can be designed as a grid. On a grate 7 can have several honeycombs 1 standing side by side and one behind the other. It is understood that in addition to square and rectangular block-shaped arrangements are possible. 2 also shows clamping bars or tie rods 9 attached to a rear housing wall 5A be hung in the middle between two honeycomb or honeycomb rows and fixed. These can be articulated joints 3 serve, with each of which a clamping bar 9 is hung movably on the rear wall. These clamping beams 9 Press across the width of the clamping bars 9 the honeycomb lying on both sides 1 towards the grate 7 and clamp or tension these honeycombs 1 thus one. The clamping beams 9 are typically all at the same height on the housing wall 5A relative to the grid 7 hooked. Typically, there are other housing sidewalls that are in 1 and 2 not shown, see 3 , About the clamping bar 9 is transverse to a traverse 11 assembled. The relative arrangement of honeycombs 1 , Clamping beams 9 and above cross-traverse 11 is also again in an enlarged section in 1 shown. By means of the transverse traverse 11 , which is mounted on the front, clamping beams can be moved simultaneously.

3 shows a side view. The already in 1 and 2 shown clamping bars 9 are with the traverse 11 connected and can by means of the crossbar 11 be moved simultaneously. The traverse 11 can thus be used as a kind of handle to open or close the system. When closed, the clamping bars run 9 as far as possible parallel to the end faces of the honeycombs 1 , see. 2 , and tension the reactor honeycombs 1 one. In order to maintain the tension, that is the clamping pressure, the traverse should typically be used 11 be locked in the closed state. 3 shows to a housing side wall 5A which a recess 6 in which the traverse 11 can be recorded when the system is closed. For the purpose of locking is a lock 8th indicated schematically. It is understood that on the opposite housing wall also a lock can be provided (not shown).

In which in the 1 . 2 and 3 However, the system described has the following problem, which is based on 4 outlined. Due to manufacturing reasons, the reactor honeycombs are subject to a length tolerance. All honeycombs are at the same level on the grid (cf. 2 , in 4 not shown), which can be considered as a reference point. Due to the length tolerance, which can also be considered as a height tolerance relative to the grating, the facing away from the grid end faces of the honeycomb can be located on slightly different levels, so have a slightly different length or height. This is in 4 for the exemplarily selected honeycomb 1A . 1B and 1C outlined in a non-to-scale manner. Here, the same elements as in the previous figures are provided with the same reference numerals, in particular the clamping bars 9 and the traverse 11 , The different height of the honeycomb due to the height tolerance now has consequences, and indeed if from above on the faces of the honeycombs through the clamping bars 9 Pressure should be applied to the honeycomb, here as an example 1A . 1B and 1C to clamp. The flow of force is indicated by the vector arrow F. Since by the described type of honeycomb fixing of the clamping bar or 9 only on two areas 13 and 14 of the system can / can, see 4 , such honeycomb, which are slightly lower, in this example, the honeycomb 1B , loosely and not or not sufficiently tensioned and thus unintentionally movable on the grid sit. In other words, such honeycombs can move, they are not or not sufficiently fixed, which is undesirable. As a solution, sealing strips are used to compensate for the length tolerance. By this measure, however, often sufficient holding force of the reactor honeycomb and guaranteed relative movements of the reactor honeycomb can be prevented. Among the shown Prerequisites are in particular by dynamic movements of a ship or a large machine, as well as suggestions from the exhaust stream relative movements on the in 4 sketched honeycomb running, which can not be fully compensated even by the use of appropriate sealing tapes. Accordingly, a tolerance-free fixation of the honeycomb is required.

It is therefore the object of the present invention to provide a constructive modification of the bracing unit, whereby unwanted relative movements can be avoided, and in particular a rich, backlash-free seat of the reactor honeycomb can be guaranteed.

The invention provides for this a tensioning system, the SCR, which comprises a plurality of square honeycombs arranged on a base plate in rows in front of a housing wall, the tensioning system for a Selective Catalytic Reduction reactor comprising: a plurality of clamping bars; each mounted on the housing wall centrally between two rows of honeycomb; wherein with the clamping bars each lying on both sides under the clamping bars honeycomb in the direction grid can be clamped so that a closed state of the system is achieved; a transverse to the clamping beam, connected to the clamping beam traverse, which is movable so that the clamping bars can simultaneously reach the closed state and leave again; wherein the cross member is lockable at least in the closed state; wherein in the side surface of the clamping bar, which points away from the traverse, in the longitudinal direction in each case at least one guide groove is incorporated; and in the at least one guide groove in the longitudinal direction in each case a flexible clamping element is guided, which protrudes in the transverse direction in each case from the guide groove.

By protruding from the guide grooves flexible elastic clamping elements, the reactor honeycomb can be kept in position.

In the tensioning system, the flexible tensioning element may comprise a corrugated steel strip and / or spring elements and / or compressed wire mesh.

These flexible clamping elements are thus provided for the tolerance compensation of the arranged in series reactor honeycomb. The tolerance compensation of the honeycomb height is achieved by individual deformation of the compensation elements, wherein those reactor honeycombs are permanently in the required position on the support grid in a strained state.

In the clamping system can be incorporated in the clamping bar, in the side of the clamping bar, pointing away from the cross member, in the longitudinal direction two guide grooves.

With two guide grooves per clamping bar and two correspondingly inserted flexible clamping elements, two juxtaposed reactor honeycombs each of one of these flexible clamping elements can be held in position.

In the tensioning system as described above, the guide groove and the flexible tensioning member may each have a rectangular cross section. In this case, the longer side of the cross-sectional area of the flexible clamping element can be greater than the depth of the guide groove.

In the tensioning system as described above, the guide groove and the flexible tension member may each have an elliptical cross section. In this case, the longer of the two axes of the ellipse can be greater than the depth of the guide groove.

There is also provided a reactor comprising the Selective Catalytic Reduction reactor, SCR, comprising: a base plate and a housing perpendicular thereto; a plurality of square honeycombs arranged on the base plate in rows in front of a housing wall of the housing; a tensioning system with a plurality of clamping bars, each mounted on the housing wall centrally between two rows of honeycomb; wherein with the clamping bars each lying on both sides under the clamping bars honeycomb in the direction grid can be clamped so that a closed state of the system is achieved; a transverse to the clamping beam, connected to the clamping beam traverse, which is movable so that the clamping bars can simultaneously reach the closed state and leave again; wherein the cross member is lockable at least in the closed state; wherein in the side surface of the clamping bar, which points away from the traverse, in the longitudinal direction in each case at least one guide groove is incorporated; and in the at least one guide groove in the longitudinal direction in each case a flexible clamping element is guided, which protrudes in the transverse direction in each case from the guide groove.

The advantages of the reactor with the clamping system have already been described above for the clamping system.

In the reactor, the flexible tensioning element may comprise a corrugated steel strip and / or spring elements and / or compressed wire mesh.

In the reactor can be incorporated in the clamping bar, in the side of the clamping bar, which points away from the traverse, in the longitudinal direction two guide grooves.

In the reactor, the guide groove and the flexible clamping element may each have a rectangular cross-section. In this case, the longer side of the cross-sectional area of the flexible clamping element can be greater than the depth of the guide groove.

In the reactor, the guide groove and the flexible clamping element may each have an elliptical cross section. In this case, the longer of the two axes of the ellipse can be greater than the depth of the guide groove.

In the reactor, the honeycombs may be similar. In this case, the side length of the square end faces of the honeycomb 200 to 300 mm and the length of the honeycomb 500 to 800 mm.

In the reactor, the clamping bars can each be secured to the housing wall with a movable articulated connection.

At this point, it should be noted that in the present case square reactor honeycombs were discussed for the SCR reactor. However, the solution to the problem is also applicable to other honeycomb shapes, such as rectangular or hexagonal honeycombs.

Embodiments of the present invention will be explained in more detail below with reference to drawings. Show it:

1 a conventional clamping system for reactor honeycombs

2 the clamping system off 1 with housing walls,

3 a side view of the clamping system 1 .

4 a schematic view of parts of a clamping system according to 1 - 3 .

5A a schematic view of clamping bars of a clamping system according to the present invention,

5B a schematic view of a section of a clamping system according to the present invention with the clamping bar from 5A .

6 a side view and a cross-sectional view of clamping bars with a flexible clamping system according to an embodiment of the present invention,

7 a side view of clamping bars with a flexible clamping system according to another embodiment of the present invention.

8th a side view of clamping bars with a flexible clamping system according to another embodiment of the present invention.

Below are the 5A to 8th explained in more detail.

Given the already in 4 problem outlined are the clamping bars 9 modified the clamping system. 5A shows that in a clamping bar 19 in the longitudinal direction of the clamping bar at least one guide groove is incorporated. For example, in the clamping bars 19 exactly two guide grooves 17 be incorporated. These can be symmetrical to the longitudinal axis of the tensioning beam 19 be provided. It is understood that a different number of guide grooves can be provided, as required by applications. These guide grooves 17 are incorporated on the underside, ie when using the clamping bars 19 in a system like that 1 - 4 Outlined, the bottom is the clamping bar 19 that long side of the clamping bars, which are downwards, ie in the direction of the grid or the base plate 7 shows, cf. 2 , The guide grooves 17 are as a guide for a flexible clamping element 15 provided, ie it is in each case a flexible clamping element 15 in a guide groove 17 inserted or inserted and where appropriate fixed properly. Typically, all have guide grooves 17 the same depth. The flexible clamping element 15 is something out of the leadership. This means, with a rectangular cross-section of the guide groove and corresponding to the clamping element to be fitted therein 15 is the longer of the two sides of the cross-sectional area of the clamping element 15 at least slightly larger than the depth of the guide groove 17 , Accordingly, for a clamping element having an elliptical cross-sectional area, the longer of the two axes may be longer than the depth of the guide groove 17 , As in 5B sketched can thus by the - in this example - two flexible clamping elements 15 the sketched, juxtaposed reactor honeycomb 1 depending on one of these flexible clamping elements 15 be held in position. Thus, the tolerance compensation of the different heights of the reactor honeycombs succeeds. Thus, the unwanted movement of the reactor honeycomb 1 be avoided.

For modifying the clamping bars 9 from the 1 - 4 towards the clamping bars 19 from the 5A and 5B is a the application conditions, ie typically used directly in the exhaust gas flow in a high temperature environment, correspondingly resistant, adapted for the exhaust gas temperatures, flexible clamping element used. 6 shows as a possibility a flexible clamping element in the form of a wavy steel sheet strip 21 , 6 shows a side view and a front view of a clamping bar 19 with such a wavy steel sheet strip 21 , Such a wavy steel sheet strip 21 is springy elastic. Balancing the different heights of the reactor honeycombs 1 through the wavy steel sheet strip 21 is in the left view in 6 clarified. The cross section of the wavy steel sheet strip 21 can, as in the right view in 6 sketched, be largely rectangular or square.

Another possibility for the formation of the flexible clamping element is in 7 outlined. In 7 are as flexible clamping element spring elements 23 intended. The selected sketch shape is for illustrative purposes only. The spring elements 23 may consist of simple feathers or represent a combination of feathers with non-resilient elements, something heads. In 7 is again the compensation of the different heights of the reactor honeycombs 1 through the spring elements 23 outlined.

Another possibility for the formation of the flexible clamping element is in 8th outlined. In 8th is inserted as a flexible clamping element a compacted wire mesh in the guide grooves. The flexible wire mesh 25 points, similar to the wavy steel sheet strip 21 out 6 or the spring elements 23 out 7 , a springy elastic property. The height compensation in relation to different heights of the reactor honeycomb 1 is in 8th outlined.

In both cases, i. Wavy sheet steel strip and wire mesh is typically a steel, preferably stainless steel, to use, which retains the required spring characteristic at operating temperature of the reactor. That even at high temperatures, e.g. higher than 600 ° C, a reversible deformability of the material must be ensured. As examples, the alloys 2.4816 (nickel-chromium-iron alloy) or 2.4819 (nickel-chromium-molybdenum alloy with tungsten) may be mentioned.

Thus, a clamping system with guide grooves and flexible clamping elements can be provided in an SCR reactor for tolerance compensation of the series-arranged reactor honeycombs. In the clamping system, the tolerance compensation of the honeycomb height is compensated by individual deformation of the flexible clamping elements. The reactor honeycombs can be kept permanently in the required position on the support grid in a clamped state. Thus, the reactor can be used in both marine and stationary environments.

LIST OF REFERENCE NUMBERS

1

honeycomb reactor

3

Adjustable connector

5A

Rear panel

5B

Housing sidewall

6

recess

7

Base plate / grid

8th

lock

9

clamping beams

11

traverse

13, 14

 contact areas

15

flexible clamping element

17

guide

19

clamping beams

21

Steel band

23

spring element

25

compacted wire mesh

Claims (15)

A Selective Catalytic Reduction Reactor Chucking System, SCR, comprising a plurality of square honeycombs arranged on a base plate in rows in front of a housing wall, the chucking system comprising: a plurality of chucks disposed respectively on the housing wall midway between two rows are hung by honeycomb; wherein with the clamping bars each lying on both sides under the clamping bars honeycomb in the direction grid can be clamped so that a closed state of the system is achieved; a transverse to the clamping beam, connected to the clamping beam traverse, which is movable so that the clamping bars can simultaneously reach the closed state and leave again; wherein the cross member is lockable at least in the closed state; characterized in that in the side surface of the clamping bar, which points away from the traverse, in the longitudinal direction in each case at least one guide groove is incorporated; and in the at least one guide groove in the longitudinal direction in each case a flexible clamping element is guided, which protrudes in the transverse direction in each case from the guide groove. Clamping system according to claim 1, characterized in that the flexible clamping element comprises a corrugated steel strip and / or spring elements and / or compressed wire mesh. Clamping system according to claim 1 or 2, characterized in that in the clamping bar, in the side of the clamping bar, away from the crossbar shows, in each case two guide grooves are incorporated in the longitudinal direction. Clamping system according to one of claims 1 to 3, characterized in that the guide groove and the flexible clamping element each have a rectangular cross-section. Tensioning system according to claim 4, characterized in that the longer side of the cross-sectional area of the flexible clamping element is greater than the depth of the guide groove. Clamping system according to one of claims 1 to 3, characterized in that the guide groove and the flexible clamping element each have an elliptical cross-section. Tensioning system according to claim 6, characterized in that the longer of the two axes of the ellipse is greater than the depth of the guide groove. Selective Catalytic Reduction reactor, SCR, comprising: a base plate and a housing perpendicular thereto; a plurality of square honeycombs arranged on the base plate in rows in front of a housing wall of the housing; a tensioning system with a plurality of clamping bars, each mounted on the housing wall centrally between two rows of honeycomb; wherein with the clamping bars each lying on both sides under the clamping bars honeycomb in the direction grid can be clamped so that a closed state of the system is achieved; a transverse to the clamping beam, connected to the clamping beam traverse, which is movable so that the clamping bars can simultaneously reach the closed state and leave again; wherein the cross member is lockable at least in the closed state; characterized in that in the side surface of the clamping bar, which points away from the traverse, in the longitudinal direction in each case at least one guide groove is incorporated; and in the at least one guide groove in the longitudinal direction in each case a flexible clamping element is guided, which protrudes in the transverse direction in each case from the guide groove. Reactor according to claim 8, characterized in that the flexible clamping element comprises a corrugated steel strip and / or spring elements and / or compressed wire mesh. Reactor according to claim 8 or 9, characterized in that in the clamping bar, in the side of the clamping bars, which points away from the traverse, in the longitudinal direction in each case two guide grooves are incorporated. Reactor according to one of claims 8 to 10, characterized in that the guide groove and the flexible clamping element each have a rectangular cross-section; wherein the longer side of the cross-sectional area of the flexible tension member is greater than the depth of the guide groove. Reactor according to one of claims 8 to 10, characterized in that the guide groove and the flexible clamping element each have an elliptical cross-section, wherein the longer of the two axes of the ellipse is greater than the depth of the guide groove. Reactor according to one of claims 8-12, characterized in that the honeycombs are similar. Reactor according to one of claims 8-13, characterized in that the side length of the square end faces of the honeycombs is 200 to 300 mm and the length of the honeycomb is 500 to 800 mm. Reactor according to one of claims 8-14, characterized in that the clamping bars are each secured with a movable articulated connection to the housing wall.

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