DE102005029988B3 - Heat exchanger protection device against growth of organisms has movable funnels in distributor chamber and collection chamber - Google Patents

Abstract

The protection device is for a heat exchanger (1) in a cooling system of tubes (2) in rows, with fluid flowing through them, and including a distributor chamber and a collection chamber. There are movable funnels in these chambers, with larger apertures sealed to the inlet and outlet apertures of at least one of the tubes. The fluid line contains a pump (8) and a heat source (4).

Description

The The invention relates to a device for protecting heat exchangers from fouling by organisms in invigorated water. Such heat exchanger come for example in watercraft and offshore platforms for use and serve mainly the heat dissipation from water cooled Drives.

It It is known that organisms, mainly barnacle larvae, are found in live water, especially seawater, to heat exchangers, usually low-temperature Seekastenkühlem settle. For example, barnacle larvae form on the tubes of these coolers Lime scale from. Once barnacles have developed on the tubes, This further barnacle larvae signals a favorable Settlement site. At this stage, barnacles are very adaptable and can survive so years.

The reduced by the organisms colonized area the cooling surface of the heat exchanger and can until the failure of the cooling function to lead. Such heat exchanger Therefore, they are structurally designed with a cooling surface that is at least 20% larger.

Farther It is known that most of these organisms do not survive temperatures above 45 ° C and flowed around strongly Not surfaces can settle. As can be shown by the example of barnacles, temperatures above 45 ° C would indeed killing of the organism lead however not to remove the formed lime scale. A restoration the original cooling surface of the heat exchanger must then be made in docking operation of the vessel. The distance The lime scale is usually done roughly mechanically and additionally by Kalkauflösung by chemical means. A lasting and effective protection the heat exchanger therefore must be before these organisms be made at any time and before their settlement.

In the patent US Pat. No. 3,309,167 A There is described an apparatus for preventing colonization of organisms in seawater on the open surfaces of submerged articles where heat is generated by means of a heating element mounted on or near the submerged article which is in heating contact with the article.

The Heating element is operated with an electric power source. The energy source is dependent controlled by the water temperature and the occurring flow.

In the patent documents WO 00/78 605 A1, EP 1 192 075 B1 . DE 199 21 433 C1 and DE 199 60 037 A1 are proposed methods and devices for anti-fouling the lake water in sea boxes of Schiften and offshore platforms locally limited, short-term and regularly repeated thermal overheating. This is achieved by connecting the high temperature engine cooling water directly to the low temperature sea chest cooler.

There are proposed devices for closing the inlet and outlet slots of the sea chest to prevent heat dissipation into the open sea. Furthermore, an additional integrated high-temperature tube bundle of the high-temperature circuit of the main engine is recommended for rapid local heating of the enclosed seawater. In the patent DE 31 23 682 C2 For example, an alloy consisting of manganese and copper, which has a face-centered cubic lattice in the single-phase structure, is proposed for protection against fouling. The alloy can be used for the production of semi-finished products.

The patent DE 41 09 197 C2 relates to a method of actively protecting against growth, in which a paint film containing free cationic or cationic groups bound to macromolecules forms a thin layer of water with extreme pH throwing by means of a variable-power DC voltage of alternating polarity on its surface.

In the patent EP 0248 050 B1 For example, there is proposed a method of preventing fouling whereby electric field of different voltage and polarity releases metal ions (copper and aluminum) and at the same time chloride ions and joins in a synergistic manner to achieve the biocidal effect.

The mentioned solutions are associated with significant disadvantages.

The disadvantages in the patent US Pat. No. 3,309,167 A consist in the fact that the execution is very complicated and expensive. Heat exchangers which usually consist of a plurality of compact arranged Einzelwärmeübertragern must be equipped with a large number of heating elements. A structural adaptation to existing heat exchanger is not possible because the heating elements must be integrated in the defined for the heat transfer and flow around volume. The heating elements are exposed to external influences due to the arrangement, such as ice and flotsam, and there is therefore a risk of destruction.

The methods and devices according to the Patent documents WO 00/78 605 A1, EP 1 192 075 B1 . DE 199 21 433 C1 and DE 199 60 037 A1 have the disadvantage that the protection of the low temperature sea chest coolers from fouling is insufficient, as the procedures can only be carried out when the main cooling circuit of the low temperature sea chest coolers is interrupted. A mixture of cooling water from different circuits of different machines and systems are usually unavoidable. Furthermore, the structural adaptation and the production engineering design are very complicated and expensive. The sea box closures must also be taken into account in the corrosion protection of the sea box. Assembly and repair are only possible in docking of the ship. The sea box closures are exposed to external effects due to the arrangement, such as ice and flotsam, and there is therefore the danger of destruction.

The disadvantage of the solution from the patent DE 31 23 682 C2 consists in too high material costs.

The solution from the patent DE 41 09 197 C2 leads due to the applied protective layer to a reduction in heat transfer performance. Damage to the active layer means failure of protection against growth by organisms.

The disadvantages in the patent EP 0 248 050 B1 are that the released metal and chloride ions cause damage to the living environment.

task The invention is to develop a device, the heat exchanger against growth by organisms in revitalized water permanently and effectively protects without the operation of the heat exchanger to interrupt and the aforementioned disadvantages of the prior Eliminate technology.

The Task is solved by that with heat exchangers, the known ones from a large number of individual heat exchangers exist, the fluid from at least one individual heat exchanger by moving and over the inlet and outlet openings the single heat exchanger positionable funnel is separated from the main cooling circuit, this fluid of a separate device consisting of a pump and a heat source, supplied and there on a higher one Temperature level is brought, the heated fluid in the separated Circulation the individual heat exchanger flows through briefly, the funnels over afterwards another single heat exchanger sealingly positioned and these operations themselves Repeat sequentially in any order for all individual heat exchangers.

The Advantages of the invention are, above all, that an antifouling is given effectively and permanently. The protection against fouling can be done without Interruption of the operation of the heat exchanger can be performed. This is especially for slow-moving watercraft and relatively stationary machines and facilities of importance. There is no mixing of fluids from different cooling circuits. The Invention is easy in the existing cooling circuit integrate. Because in the invention only a very small Amount of fluid to a higher one Temperature level must be brought, is only a very small amount of energy necessary. Furthermore, the closing of the inlet and outlet slots the sea chest, in which the heat exchanger is located, not required. The water revived by organisms is not poisoned or contaminated. There are no expensive materials for the individual heat exchanger needed. The protection against fouling is caused by external influences, such as Ice and flotsam, not affected.

The Invention will be described below with reference to drawings, in the advantageous embodiments are shown.

It demonstrate:

1 : Scheme of a cooling circuit with integrated anti-fouling protection, anti-fouling is deactivated

2 : as 1 with activated antifouling of the first individual heat exchanger

3 : as 1 with activated antifouling of the second individual heat exchanger

4 Partial section of a low-temperature sea chest cooler transverse to the rows of tubes and scheme of the separate circuit

5 : Partial section of a low-temperature sea chest cooler along the rows of pipes in front of the partition wall looking into the collection chamber

In 1 the diagram of a refrigeration cycle with a low temperature sea chest cooler is shown. The fluid from a water-cooled engine of a ship reaches the heat exchanger in the low-temperature circuit 1 with an inlet temperature of 40-45 ° C. The fluid flow is divided into several individual heat exchangers 2 on, for example wise on several rows of pipes. After passing through all individual heat exchangers 2 the fluid reaches the outlet of the heat exchanger 1 and is thereby by the individual heat exchanger 2 around flowing seawater cooled to 36 ° C. An advantageous embodiment of the device is integrated into the scheme, but not activated.

In 2 is the same scheme as in 1 shown. The anti-fouling is activated by acting on a single heat exchanger 2 with the adjacent directional valves 3 the fluid is separated from the main cooling circuit, the operating switch 5 the circuit with the power source 6 to activate the heater 4 and the engine 7 to operate the pump 8th closes, the fluid from the single heat exchanger 2 is heated by the, after the flow through the secondary circuit on the temperature 9 determined temperature of 50 ° C is reached and held for a period of at least one minute. The main cooling circuit remains in operation during this time. After expiration of the holding time to protect the first Einzelwärmeübertragers 2 become the directional valves 3 of the next individual heat exchanger 2 switched so that this single heat exchanger 2 is separated from the main cooling circuit. The directional valves 3 of the first individual heat exchanger 2 release the fluid for the main cooling circuit again. The state of the main and secondary cooling circuit thus achieved is in 3 shown. The procedure described is repeated for all individual heat exchangers 2 and can be done continuously or intermittently.

The first constructive embodiment is in 4 and 5 shown. In 4 a known low temperature sea chest cooler is shown consisting of a cooler base plate 18 , arranged in rows of pipes pipe bends 2 and a hood 17 passing through a partition 19 in distribution chamber 12 and collection chamber 13 is shared. The pipe bends 2 of the sea chest cooler are in water animated with organisms 10 dipped. The attached side view is in 5 shown. In addition to the conventional main cooling circuit of the sea chest cooler, starting from the inlet connection 11 through the distribution chamber 12 and the tube bends arranged in rows of tubes 2 to the collection chamber 13 and the return pipe 14 in which all pipe bends 2 be traversed, the device described here allows the flow through individual rows of tubes. The respective rows of tubes are on their supply and return side respectively by movable sealed funnels 15 covered. The smaller openings of the funnels 15 are via a movable fluid line 16 in series with a heater 4 and a pump 8th connected so that a separate circuit is created. In the direction of flow in front of the pump 8th is a temperature measuring device 9 provided that allows the detection of the return temperature and thus a control of the heating or pump power. The heater 4 is with the engine 7 , the pump 8th and a power switch 5 electrically connected in series and is powered by a power source 6 provided. The funnels 15 are provided with a drive, preferably a driven by an electric motor spindle, which allows a propulsion in the longitudinal direction of the sea chest cooler and thus a positioning over any row of pipes. As a result, all rows of tubes can be heated separately in any order.

The second constructive embodiment corresponds to the first constructional example with the difference that the movement of the funnels 15 done in two directions. Before the actual movement along the radiator base plate 18 from one row of pipes to the next, the funnels become 15 from the radiator base plate 18 lifted and lowered over the next row of pipes again.

1

Heat exchanger

2

Single heat exchanger, Elbows

3

way valve

4

heat source

5

switches

6

power source

7

engine

8th

pump

9

thermometer

10

seawater

11

inlet connection

12

distribution chamber

13

plenum

14

Return connectors

15

funnel

16

fluid line

17

Hood

18

Cooler base

19

partition wall

Claims (7)

Device for protection against fouling with organisms on heat exchangers ( 1 ), in particular low-temperature Seekastenkühlem, consisting of an inlet nozzle ( 11 ) in a distribution chamber ( 12 ), a plurality of parallel arranged, flowed through by a fluid Einzelwärmeübertragern ( 2 ), in particular pipe bends which are arranged in rows of tubes and in the living with organisms ( 10 ), whose inlet openings with the distribution chamber ( 12 ) are connected and the outlet openings of said individual heat exchanger ( 2 ) in a collection chamber ( 13 ), at which a return pipe ( 14 ), characterized in that in the Verteilerkam mer ( 12 ) and the collection chamber ( 13 ) movable funnels ( 15 ) with their larger openings to the inlet and outlet openings of at least one Einzelwärmeübertragers ( 2 ) are arranged sealingly, a fluid line ( 16 ) the funnels ( 15 ) at their smaller openings and in the fluid line ( 16 ) one pump at a time ( 8th ) and a heat source ( 4 ) are switched. Apparatus according to claim 1, characterized in that the accumulated heat transfer surface of the separately operated individual heat exchanger ( 2 ) does not exceed 10% of the total heat transfer area of the heat exchanger ( 1 ). Device according to claims 1 or 2, characterized in that the temperature in the return of the separately operated individual heat exchanger ( 2 ) is at least 45 ° C. Device according to claims 1 to 3, characterized in that a single heat exchanger ( 2 ) is flowed through in the separate circuit for at least one minute. Device according to claim 1, characterized in that the funnels ( 15 ) consist of a plastic. Device according to claim 1, characterized in that the heat source ( 4 ) is a controllable electrical heating element. Device according to claim 1, characterized in that the pump ( 8th ) is a centrifugal pump.