DE202015105722U1 - adsorption - Google Patents

Abstract

Adsorption tower (3), characterized in that a certain number of heat exchanger tubes (2) is introduced into the housing (1) of the adsorption tower (3), wherein an end of the heat exchanger tube located in the adsorption tower is in the activated carbon or activated carbon fiber layer (4). extends and an outside of the adsorption tower (3) befindliches end is disposed in the air.

Description

TECHNICAL AREA

The present utility model relates to an adsorption tower.

STATE OF THE ART

The adsorption tower is a product of environmental protection equipment that adsorbs the organic components of exhaust gases. With the help of the strong adsorption capacity of activated carbon or activated carbon fibers, the device adsorbs and separates the organic molecules in the exhaust gas, thereby purifying the organic waste gases. In the specific process, an organic waste gas is conveyed through the pipeline into the adsorption tower. The organic gas part in the gas flows in the flow direction of the gas into the adsorption layer of the activated carbon or activated carbon fibers. When the organic gas enters the carbon layer, the organic gas is adsorbed by the activated carbon or activated carbon fibers, and the purified air passes through the carbon layer and is discharged into the atmosphere. However, the structure of the adsorption tower in the market can not timely discharge the adsorption reaction heat generated upon adsorption by the activated carbon or activated carbon fiber layer.

CONTENT OF THE PRESENT USE PATTERN

It is the technical problem to be solved of the present utility model to provide an efficient self-cooling stationary adsorption tower which can solve the partial overheating which occurs in the operation of an activated carbon or activated carbon fiber adsorption tower.

In order to solve the above technical problems, a technical solution of the present utility model relates to:

An adsorption tower in which a certain number of heat exchange tubes are inserted into the housing of the adsorption tower, wherein an end of the heat exchanger tube located in the adsorption tower extends into the activated carbon or activated carbon fiber layer and an end outside of the adsorption tower is located in the air. Via the heat exchanger tubes, the heat of reaction in the adsorption tower is transferred to the exterior of the adsorption tower, natural cooling being carried out via the outside air.

A further defined technical solution of the present utility model relates to the efficient self-cooling stationary adsorption tower, wherein the heat exchanger tube is a total pipe slant structure or is formed by a horizontal structure in the adsorption tower and a slant structure located outside the adsorption tower, and wherein the slant portion and the horizontal direction include a skew angle of 0 to 25 °. The oblique mounting of the heat exchanger tubes is conducive to the flow of the medium in the heat exchanger tubes and the heat transfer.

In the efficient self-cooling stationary adsorption tower, an anti-scald plate is disposed on the outer wall of the heat exchanger tube.

The present utility model has the following advantages: the present utility model releases the heat released by the activated carbon layer during the gas adsorption process in time to the outside of the tower to reduce the temperature of the adsorbent bed layer, thereby controlling the adsorption temperature of the entire apparatus within 30-80 ° C so as to improve the adsorption efficiency of the activated carbons or the activated carbon fibers; the temperature level of the activated carbon or activated carbon fiber layer can be controlled within 1-2 / 1 m; the heat can be drained in time, which is beneficial for the operational safety of the device.

BRIEF DESCRIPTION OF THE DRAWING

1 shows a schematic structural view of the present utility model.

2 shows a plan view of the present utility model

DETAILED DESCRIPTION

First embodiment

An efficient self-cooling stationary adsorption tower in the present embodiment, structure as in 1 and 2 shown in which a certain number of heat exchanger tubes 2 into the housing 1 of the adsorption tower 3 is inserted, with one in the adsorption tower 3 befindliches end of the heat exchanger tube into the activated carbon or activated carbon fiber layer 4 extends and one outside the adsorption tower 3 located end is located in the air. About the heat exchanger tubes 2 the heat of reaction in the adsorption tower is transferred to the exterior of the adsorption tower, with natural cooling being carried out via the outside air. About welding is a connection between the heat exchanger tubes 2 and the housing 1 produced. The heat exchanger tubes 2 are layered and grouped on Adsorptionsturm 3 Installed. A section of the heat exchanger tube 2 is located in the activated carbon or activated carbon fiber layer and a section is in the air.

For the section of the heat exchanger tube located in the adsorption tower 2 If a light guide tube or finned tube is used, a finned tube is used for the portion located outside the adsorption tower, so that the heat transfer can be enhanced, which is conducive to a timely discharge of the heat. The heat exchanger tube 2 is an overall pipe slant structure or is formed by a horizontal structure located in the adsorption tower and a slant structure located outside the adsorption tower, wherein the slant portion and the horizontal direction include a skew angle of 0 to 25 °. The oblique mounting of the heat exchanger tubes is conducive to the flow of the medium in the heat exchanger tubes and the heat transfer.

The external heat pipe with fins of the heat exchanger tube 2 is provided with a scalding protection plate. The working medium of the heat exchanger tube 2 is water or alcohol and other working fluids of low or medium temperature.

Besides the above embodiments, the present utility model may have other embodiments. All technical solutions formed by equivalent or equivalent modifications should be considered to be within the scope of this utility model.

Claims (3)

Adsorption tower ( 3 ), characterized in that a certain number of heat exchanger tubes ( 2 ) in the housing ( 1 ) of the adsorption tower ( 3 ), wherein an end of the heat exchanger tube located in the adsorption tower is in the activated carbon or activated carbon fiber layer ( 4 ) and one outside the adsorption tower ( 3 ) located in the air. Adsorption tower ( 3 ) according to claim 1, characterized in that the heat exchanger tube ( 2 ) has an overall pipe slanted structure or by a in the adsorption tower ( 3 ) and one outside the adsorption tower ( 3 ) is formed, and wherein the inclined portion and the horizontal direction include a skew angle of 0 to 25 °. Adsorption tower according to claim 1 or 2, characterized in that on the outer wall of the heat exchanger tube ( 2 ) a scald protection plate is arranged.

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