NO329277B1 - Process for preventing the development of biological material in a water-based heat exchanger system - Google Patents

Abstract

A method of at least suppressing the development of biological material in a heat exchanger installation (1) adapted to be able to circulate water through pipelines (C, D, E, M, SV), valves (WV, AV) and at least one evaporator ( VI-V4), and where water, especially seawater, is a heat energy source, the method comprising the steps of: a) a circulation circuit through the heat exchanger installation for the water which is the heat energy source is isolated from the water source by inlet (S1-S8) and outlet (W1- W2) is closed; b) an antifouling agent or a mixture of several antifouling agents is dosed intermittently into the water in the closed circulation circuit (P1-P4, M, VI-V4) to form treatment water; c) the treatment water is circulated in the closed circulation circuit (P1-P4, M, VI-V4); d) the treatment water is pumped out of the circulation circuit (P1-P4, M, V1-V4) and into a storage tank (S); and e) the inlet (P1-P4, M, V1-V4) inlet (S1-S8) and outlet (W1-W2) inlet are opened to supply water from the water source.

Description

PROCEDURE FOR PREVENTING THE DEVELOPMENT OF BIOLOGICAL MATERIAL IN A WATER BASED HEAT EXCHANGER SYSTEM

The invention relates to a procedure for preventing or limiting the development of biological material in a water-based heat exchanger installation, more specifically to prevent or suppress growth, i.e. the growth of algae, shells, etc., in seawater-carrying lines and the like in a heat exchanger installation that uses water as a heat energy source .

It is a well-known phenomenon that biological material such as algae, shells, etc., shows strong growth on installations in water, for example on ships, quays and offshore installations. In seawater-carrying lines, such growth can lead to a greatly reduced transport capacity. The problem can become even clearer in heat exchangers that use seawater as a heat energy source, as the heat transfer capacity can be significantly reduced.

It is also known that various types of chemicals dampen or prevent such growth. A well-known agent is the bottom substances that are smeared on the parts of a ship that are below the waterline. Sodium hypochlorite is an example of an antifouling agent added to water flowing through an installation.

The use of chemicals will usually result in the environment around the installation being exposed to a greater or lesser degree of unwanted influence. In connection with a seawater-based heat exchanger, which exhibits a large flow of water, for example 20,000 m<3>/hour, continuous addition of chemicals to the flowing water will result in a large chemical consumption that is spread out in a limited area, and that a heat exchanger is essentially stationary.

US3647687 describes a process for washing out deposits in a sewage sludge treatment system. A separate tank is used with solvent that is circulated in the circuit after this has been shut off for the medium that normally circulates in the circuit. After cleaning, the solvent is returned to the tank, and the system is switched to normal sludge treatment. Changeover takes place by maneuvering a number of valves. The purpose is to maintain the thermal efficiency of the system, as oxidation of the sewage sludge releases heat in a heat exchanger. A main purpose is to describe a valve system that isolates a reactor from the rest of the system when cleaning is to be carried out, so that the pressure in the reactor can be maintained while cleaning is in progress.

The purpose of the invention is to remedy or to reduce at least one of the disadvantages of known technology.

The purpose is achieved by features that are stated in the description below and in subsequent patent claims.

The invention relates to a method for at least mitigating the development of biological material in a heat exchanger installation which is integrated in a regasification plant for natural gas and is designed to be able to circulate water through pipelines, valves and at least one evaporator, and where water, in particular seawater, is a heat energy source, and where the procedure comprises the following steps: a) a circulation circuit through the heat exchanger installation for the water which is the heat energy source, is isolated from the water source by closing the inlet and outlet; b) one antifouling agent or a mixture of several antifouling agents is dosed at intervals into the water in the closed circulation circuit and forms treatment water; c) the treatment water is circulated in the closed circulation circuit; d) the treatment water is pumped out of the circulation circuit and into a storage tank;

and

e) the inlet and outlet of the circulation circuit are opened for the supply of water from the water source.

Repeated treatment of the water preferably comprises the steps:

f) the circulation circuit for the water, which is the heat energy source, is isolated from the water source by closing the inlet and outlet; g) the water contained by the circulation circuit is pumped out of the circulation circuit; h) the treatment water is pumped from the storage tank into the circulation circuit;

i) the antifouling agent or the mixture of several antifouling agents is dosed at an interval shown in

the treatment water in the closed circulation circuit to provide a prescribed concentration of antifouling agent in the treatment water in the circulation circuit;

j) the treatment water is circulated in the closed circulation circuit;

k) the treatment water is pumped out of the circulation circuit and into the storage tank; and

I) the circulation circuit's inlet and outlet are opened for the supply of water from the water source.

The antifouling agent is preferably supplied at least at the at least one evaporator.

The antifouling agent that is supplied is adapted to the prevailing flora and fauna in the water used as a heat energy source, as a specialist in the area will choose one or more suitable antifouling agents in a suitable concentration based on knowledge of the nature of the water and the agent's antifouling properties towards the unwanted organisms .

The antifouling agent is, for example, a metal-based chemical composition or a gas. An example of a metal-based chemical composition is sodium hypochlorite. An example of a gas is ozone.

The dosage of the antifouling agent or the mixture of several antifouling agents to the water takes place continuously or at intervals.

The intermittent supply of the antifouling agent or the mixture of antifouling agents is advantageously repeated within a time interval of from a few hours to several days in order for a desired concentration of active agent to be restored in the water.

The total treatment time preferably extends over a period of one to several days.

The regasification plant is located on a floating installation, alternatively on a fixed installation on water or alternatively on a fixed, land-based installation.

The storage tank is advantageously located on a fixed installation on land or at sea or on a floating installation.

The storage tank is advantageously located on an installation that is movable in relation to the heat exchanger installation.

In what follows, a non-limiting example of a preferred embodiment is described which is visualized in the accompanying drawing, where: Fig. 1 shows a simplified flow diagram for a heat exchanger installation according to the invention.

Reference is made to the figure where a heat exchanger installation 1 is provided with several heat exchangers V1-V4 which supply energy to a heat-demanding process plant (not shown). The heat energy source is water that is pumped using the main pumps P1-P4 from a reservoir, for example sea, fjord, lake, river (not shown). On the suction side of the pumps P1-P4, several intake filters S1-S8 are placed for coarse filtering of the water. Fine filters F1-F4 are installed on the pressure side of the pumps Pl-P4 to remove fine particles from the water. The water is released back into the reservoir via outlet W1-W2. The circulation circuits for water can be controlled using a series of valves WV. A conduit M is arranged to conduct the water.

An antifouling agent system A, which is designed to create, mix and/or dose an antifouling agent or a mixture of several antifouling agents, is connected to a wiring network C for the supply of antifouling agent to the heat exchanger installation's 1 heat exchangers V1-V4 via

several valves AV (shown in a smaller size than the valves WV for controlling the circulation of water during ordinary heat exchanger operation). A wiring network D further connects the heat exchangers V1-V4 with circulation pumps P5-P6 for treatment water, the main pumps P1-P4 and the fine filters F1-F4 for circulation within the heat exchanger installation 1 of treatment water containing a prescribed concentration of antifouling agent.

The circulation pumps P5-P6 are also connected to a wiring network SV which is arranged for connection to a storage tank S for used treatment water that contains antifouling agent residues and degradation products from the treatment process.

While the main pumps P1-P4 are designed for a water delivery of typically 20,000 m<3> per hour for a heat exchanger installation for a natural gas regasification plant, the circulation pumps P5-P6 are typically designed to circulate 250-300 m<3> of treatment water over a period of several hours.

The wiring network C for the supply of antifouling agent and the wiring network E for the transfer of used treatment water between the heat exchanger installation 1 and the storage tank S are drawn with a dashed line for the sake of clarity, while the ordinary circulation network in the heat exchanger installation 1 is drawn with a solid line.

If treatment of the heat exchanger installation 1 is required, the flow of water is stopped by stopping the main pumps P1-P4. The valves WV at the intake filters S1-S8 and between the heat exchangers V1-V4 and the outlets W1-W2 are closed. A volume of water is now isolated from the water source by being shut off in the heat exchanger installation 1.

When the heat exchanger installation 1 is treated for the first time with an antifouling agent or when there is no access to used treatment water from the storage tank S, the water that is shut off in the heat exchanger installation 1 is used to create treatment water by adding an antifouling agent to this water.

The valves AV connecting the wiring harnesses C, D, E, and M are opened. Antifouling agent is dosed by means of the antifouling agent plant A into the heat exchanger installation 1 through the wiring network C in the prescribed quantity, and the circulation pumps P5-P6 circulate the mixture of water and antifouling agent (also called treatment water) through the main pumps P1-P4, the fine filters F1-F4, the heat exchangers V1-V4 and wiring harness M, D and E.

When accessing used treatment water from the storage tank S, via the wiring network SV, the water that is shut off in the heat exchanger installation 1 is first evacuated. The water, which does not contain an antifouling agent, is pumped out into the water source. The storage tank S is then connected to the heat exchanger installation 1 via the wiring network SV, and a prescribed amount of treatment water is pumped into the heat exchanger installation 1 circulation circuit. Antifouling agent in a prescribed quantity is then added as described above.

The treatment water is then circulated for a prescribed period. At certain intervals, a new antifouling agent is dosed to the treatment water to maintain a desired concentration of antifouling agent in the treatment water, as the antifouling agent breaks down during the treatment.

A typical treatment process can be the following:

When the treatment is finished, the used treatment water is pumped into the storage tank S via the pipe network SV, and then the heat exchanger installation is filled with water from the water source, and ordinary water circulation for heat exchange is started using the prescribed operation of valves and pumps.

At a receiving facility for natural gas, there will typically be several regasification units to ensure a steady supply of gas, for example when a first ship is emptied and the unloading

of a second ship is launched. The treatment of a regasification unit's heat exchanger installation can then take place during the period while one regasification unit is not in operation, waiting for the second ship to be emptied and the unloading of a third ship to start. This period is sufficiently long for the treatment according to the invention to be carried out.

Claims (10)

1. Procedure for at least mitigating the development of biological material in a heat exchanger installation (1) integrated in a regasification plant for natural gas and which is designed to be able to circulate water through pipelines (C, D, E, M, SV), valves ( WV, AV) and at least one evaporator (V1-V4), and where water, in particular seawater, is a heat energy source, characterized in that the procedure includes the following steps: a) a circulation circuit through the heat exchanger installation for the water that is the heat energy source, is isolated from the water source by inlet (S1-S8) and outlet (W1-W2) are closed; b) one antifouling agent or a mixture of several antifouling agents is dosed at intervals into the water in the closed circulation circuit (P1-P4, M, V1-V4) and forms treatment water; c) the treatment water is circulated in the closed circulation circuit (Pl-P4, M, V1-V4); d) the treatment water is pumped out of the circulation circuit (P1-P4, M, VI-V4) and into a storage tank (S); and e) the inlet (S1-S8) and outlet (Wl-V8) of the circulation circuit (P1-P4, M, V1-V4) are opened for the supply of water from the water source. 2. Method according to claim 1, characterized in that repeated processing includes the steps: f) the circulation circuit (P1-P4, M, V1-V4) for the water which is the heat energy source, is isolated from the water source by inlet (S1-S8) and outlet (W1-W2) is closed; g) the water contained by the circulation circuit (P1-P4, M, V1-V4) is pumped out of the circulation circuit (P1-P4, M, V1-V4); h) treatment water is pumped from the storage tank (S) into the circulation circuit (P1-P4, M, V1-V4); i) the antifouling agent or the mixture of several antifouling agents is dosed intermittently into the treatment water in the closed circulation circuit (P1-P4, M, V1-V4) to form a prescribed concentration of antifouling agent in the treatment water in the circulation circuit (P1-P4, M, V1-V4) ); j) the treatment water is circulated in the closed circulation circuit (Pl-P4, M, V1-V4); k) the treatment water is pumped out of the circulation circuit (P1-P4, M, VI-V4) and into the storage tank (S); and I) the circulation circuit's inlet (S1-S8) and outlet (Wl-W2) are opened for the supply of water from the water source. 3. Method according to claim 1, characterized in that the antifouling agent is at least supplied by at least one evaporator (VI-V4). 4. Method according to claim 1, characterized in that the antifouling agent is a metal-based chemical composition or a gas. 5. Method according to claim 1 or 2, characterized in that the dosing of the antifouling agent or mixtures of several antifouling agents to the water takes place continuously or at intervals. 6. Method according to claim 1 or 2, characterized in that the intermittent supply of the antifouling agent or the mixture of several antifouling agents is repeated within a time interval of from a few hours to several days. 7. Procedure according to claim 1, characterized in that the total processing time extends over a period of from one to several days. 8. Procedure according to claim 1, characterized in that the regasification plant is located on a floating or fixed installation on water or on a fixed, land-based installation. 9. Method according to claim 1, characterized in that the storage tank (S) is located on a fixed installation on land or at sea or on a floating installation. 10. Method according to claim 9, characterized in that the storage tank (S) is located on an installation which is movable in relation to the heat exchanger installation (1).