DE19630482A1 - Heat exchanger - Google Patents

Description

The invention relates to a heat exchanger with numerous flowed through by a cooling fluid, approximately parallel to each other trending heat exchange tubes in one of hot gas flow channel are arranged, each Heat exchange tube is wound.

The gases to be cooled in this type of heat exchanger often contain dust and various types of vapors that deposits and caking occur during operation form the outside of the heat exchange tubes. Such toppings heat transfer on the pipes deteriorate.

The invention has for its object coverings and Caking on the heat exchange tubes on simple and effective way to eliminate. This is achieved according to the invention in the heat exchanger of the type mentioned in that the heat exchange tubes are stationary in the area of their turns are held and the central area of the heat exchange tubes is in contact with a tap tube between the turns, where jerky movements of the knocking tube vibrations in the Generate heat exchange tubes. Solve through the vibrations the rubbers and fall off.  

The knock pipe, which vibrates in the Heat exchange tubes can be produced in various ways be trained. The knock pipe advantageously runs in the Area of contact with the heat exchange tubes, for example perpendicular to the heat exchange tubes. This can cause bumps intense vibrations in the knocking tube generate the heat exchange tubes.

It is not absolutely necessary that the knock pipe with the Heat exchange tubes is connected, but this connection is expedient to a stable arrangement even in continuous operation to have. Usually, the knock pipe is wound several times and designed to be elastically movable, with impacts on it Turns are transferred to the heat exchange tubes. Here it is possible to only use the heat exchange tubes to initiate in sections.

Design options for the heat exchanger are included Help explained in the drawing. It shows:

Fig. 1 is a horizontal section along the line II in Fig. 2 by a vertical flow gas duct having heat exchange tubes and a tube knock in the view from above,

Fig. 2 is a vertical section along the line II-II in Fig. 1,

Fig. 3 is a vertical section along the line III-III in Figs. 1 and 2

Fig. 4 is a view analogous to Fig. 3 of a variant of a knock pipe in a schematic representation and

Fig. 5 shows a knock pipe, which cooperates with two heat exchange pipes, in a perspective view.

The gas duct ( 1 ) shown in cross section in FIG. 1 and flowed through by hot gases has a plurality of heat exchange tubes ( 2 ) on the inside. In the vertical section along the line II-II in Fig. 1 through the channel ( 1 ), a single heat exchange tube ( 2 ) is visible and it is in Fig. 2 in its form with several turns ( 2 a), ( 2 b) and ( 2 c). In the area of the turns, the heat exchange tubes ( 2 ) are attached to supports ( 3 ) which are themselves connected to vertical support tubes ( 4 ). In Fig. 1, the connection between the supports ( 3 ) and the heat exchange tubes ( 2 ) is not shown for better clarity. The heat exchange tubes ( 2 ) are in connection with collecting chambers ( 6 ) and ( 7 ) for the supply and discharge of cooling fluid, for. B. steam, water, air or oil.

A tapping tube ( 8 ), which is shown in view in Fig. 3, runs perpendicular to the heat exchange tubes ( 2 ) and is coupled to them. In the present case, the coupling consists of tabs ( 9 ) which are welded to the knocking tube ( 8 ) and an approximately horizontal part of a heat exchange tube. In Fig. 1 the tabs are not shown for clarity. Instead of tabs z. B. sleeves can also be used.

Just like the heat exchange tubes, both the support tubes ( 4 ) and the knock tube ( 8 ) can be designed with cooling fluid flowing through them. The knocking tube ( 8 ) has a certain elasticity in the direction perpendicular to the heat exchange tubes ( 2 ) due to its sinuous shape, see FIG. 3. A tappet ( 10 ) is connected to the tapping tube and is guided through the wall of the channel ( 1 ) to the outside. By sudden movements of the plunger ( 10 ), for. B. by blows with a hammer, the heat exchange tubes ( 2 ) connected to the knock tube ( 8 ) are pushed perpendicular to their longitudinal axis and thereby set in short vibrations. These vibrations cause deposits on the outside of the heat exchange tubes ( 2 ) to come off. The jerky movement of the tapping tube ( 8 ) from the outside can not only mechanically but z. B. also be done pneumatically or electromagnetically.

The tapping tube ( 8 a) shown schematically in Fig. 4 is wound several times and has a plurality of plungers ( 10 ) guided outwards. The connection of this tapping tube ( 8 a) with the associated heat exchange tubes, which is to be considered analogously to FIG. 3, was omitted in FIG. 4. By bumping only one of several plungers ( 10 ) present, only individual areas of the heat exchange tubes can be vibrated and thereby cleaned.

The variant of a knock pipe ( 8 b) shown in FIG. 5 shows the guidance of the knock pipe ( 8 b) which is kinked in the area of the windings ( 18 ). This shape of the turns ensures that the impact of a single tappet leads to vibrations in the knock tube, which are not also transmitted to other areas of the knock tube. Otherwise, the reference numerals in FIG. 5 have the meaning already explained above.

The tapping of the heat exchange tubes according to the invention can for both horizontal and vertical flow Channels or boilers can be used.

Claims (4)

1. Heat exchanger with numerous heat exchange tubes through which a cooling fluid flows, approximately parallel to one another and arranged in a channel through which hot gas flows, each heat exchange tube being wound, characterized in that the heat exchange tubes are held stationary in the area of their turns and the area the heat exchange tubes between the turns is in contact with a knock tube, jerky movements of the knock tube producing vibrations in the heat exchange tubes. 2. Heat exchanger according to claim 1, characterized in that the tap tube in the area of contact with the Heat exchange tubes approximately perpendicular to the Heat exchange tubes runs. 3. Heat exchanger according to claim 1 or 2, characterized characterized in that the tap tube with the Heat exchange tubes is connected. 4. Heat exchanger according to claim 1 or one of the following, characterized in that the tapping tube is wound several times and is designed to be elastically movable.