JP5431463B2 - Sea chest cooler with built-in deposit protection system - Google Patents

Description

  The present invention relates to a sea chest cooler (or a seabox cooler) in a ship and a marine work table. In the ship and the marine work table, barnacles, shellfish and other attached organisms are periodically repeated by a built-in deposit protection system. It is killed by possible overheating (or heating).

(Background technology and its problems)
Deposits on ships, ship components and piping systems, and components of the deposits, increase sharply, especially due to increased water pollution. Various methods have been tried internationally to reduce or avoid these deposits.

  Patent Document 1 discloses pipes, filters, heat exchangers, valves, pumps, sea chest coolers, etc. that are in contact with seawater temporarily or continuously in a sea chest (or a casing or box of a seawater inlet). Describes an effective and environmentally friendly method and apparatus for controlling and avoiding biofouling for ships, marine work benches and the like, on the basis of the problem.

  The method includes isolating seawater in the sea chest from the surrounding environment, removing the sea chest cooler from cooling operation and mechanically switching the high temperature circuit to the sea chest cooler to be protected. Is characterized by being used for the heating of trapped seawater, which is locally limited, short-term and periodically repeatable.

  An apparatus for carrying out the method includes an individual sea chest of the sea water system, pipes and flow paths connecting the sea chest, and a sea chest cooler, a pump and a valve installed in the sea water system. Component to form a separate partial system, which results in a short-term, locally limited periodic overheating of the confined seawater, so that the entire seawater system is Protected from deposits. A further feature is that the partial system is divided into an active partial system and a passive partial system. At this time, during offshore operation (or normal operation), the shutter in the active sea chest is opened, the shut-off valve is closed, and the passive partial system is in the cleaning operation with the shutter closed, so that the passive sea chest is The components inside are locally limited, short-term and periodically repetitively overheated.

  The disadvantage of the invention is that modifications in the ship structure are essential, for example, it is essential to install a flap for closing the discharge slit of the sea chest. In some cases, the maintenance work of the closing mechanism, which is necessary in some cases, is possible only in the dock, leading to unplanned interruption of the ship operation.

  In patent document 2, the apparatus which made it the subject to protect this heat exchanger from a deposit | attachment continuously and effectively, without interrupting operation | movement of a heat exchanger is disclosed.

  The problem is that in a heat exchanger consisting of a number of individual heat exchangers, at least one individual heat exchanger is moved by a movable hopper positioned through the inlet and return openings of the individual heat exchanger. This is solved by separating the liquid from the actual cooling circuit. Using a pump, the liquid is conveyed into a separate circulation circuit, flows through a heat source and is brought to a higher temperature level in the heat source. The heated liquid is then recirculated through the individual heat exchanger separated from the cooling circuit. After completion of this heating cycle, the hopper is taken to a closed position on another individual heat exchanger, whereby the procedure is repeated for all individual heat exchangers.

DE 19921433 C1 DE 102005029988 B3

  The disadvantage of the device of Patent Document 2 is that the individual heat exchanger is removed from the cooling circuit, and therefore can be protected from deposits in a separate heating circuit so that it flows into the inlet in the same individual heat exchanger. The inflow hopper and the outflow hopper must be mechanically connected to each other in different chambers of the cooler lid so that the outflow hopper can be positioned on the outflow section. The technical structure for mechanically connecting both hoppers to each other is extremely complex and prone to failure. Furthermore, the device described in US Pat. No. 6,057,059 uses a separate electric heater for heating, which incurs additional energy demands up to an estimated 60 KW, and therefore sustainability and environmental protection reasons. Should be avoided.

  The object of the present invention is to continuously heat a predetermined number of tube rows using a simple apparatus as much as possible in a structural form of a sea chest cooler that already resists deposits by microorganisms such as barnacles, shellfish and algae. It is envisaged that the sea chest cooler can be protected both automatically during actual cooling operation and when stopped. This should be done without system separation. The required heating energy should be extracted energetically efficiently, for example from the hot hot circulation circuit of the main engine or auxiliary diesel.

The object is solved according to the invention according to the features of claim 1 .
That is, according to one aspect of the present invention, there is provided a sea chest cooler with a built-in deposit protection system for killing barnacles, shellfish and other attached organisms by periodically repeated overheating. The cooler includes a tube bundle having a plurality of heat exchanger tubes, and the deposit protection system is composed of a thermal anti-fouling TAS device, and at least one partial surface of the tube plate is circular or square. Formed by co-location with the outlet openings of the plurality of heat exchanger tubes of the first cooling circuit, in series connection of the inlet openings of the plurality of heat exchanger tubes of the second cooling circuit, and thus with the cooler lid In the coupled state, a nozzle chamber is provided, and in the nozzle chamber, a TAS nozzle capable of rotating the TAS device is provided, and the TAS nozzle is the circular or square partial surface of the tube plate. The heat exchanger tube, which covers the individual circular segments of the heat exchanger tubes of the tube bundle and thus is sealed and isolated from the surroundings, is usually supplied by separately supplied heated water. Protected against seawater-side deposits during or outside of the normal cooling operation, and further rotation of the TAS device results in a new circular segment of individual heat exchanger tubes in the tube sheet. , Covered by the TAS nozzle.
The reference numerals attached to the claims of the present application are only for facilitating the understanding of the present invention, and are not intended to limit the present invention to the embodiments described in the subsequent paragraphs. I will add.

BEST MODE FOR CARRYING OUT THE INVENTION

In the present invention, the following modes are possible.
(Mode 1) A sea chest cooler with a built-in deposit protection system for killing barnacles, shellfish and other attached organisms by repetitive overheating, which is substantially circular or square in the tube sheet A plurality of heat exchanger tubes of the tube bundle are arranged in the sea chest cooler so as to form at least one partial surface of the tube bundle, and a TAS nozzle of a mechanical TAS device is installed in the nozzle chamber, Individual heat exchanger tubes are covered, and then the heat exchanger tubes sealed and isolated from the surroundings are in normal cooling operation with separately supplied heated water Or protect against seawater deposits outside of normal cooling operation.
(Mode 2) Preferably, the heat exchanger tube has a structured surface, thereby improving heat transfer and increasing adhesion resistance to deposits.
(Mode 3) The TAS apparatus is preferably a rotary apparatus for covering and heating a new circular segment composed of individual heat exchanger tubes by further rotation.
(Form 4) It is preferable that the rotation execution part as a part of said TAS apparatus seals the water space in a cooler cover part toward outward.
(Mode 5) It is preferable that a TAS nozzle is attached to the rotation execution unit in the water space, and the outer shape of the TAS nozzle is adapted to one or a plurality of circular segments.
(Mode 6) An additional lift unit is attached, which lifts the TAS nozzle before each further rotation in the TAS device, lowers it again after the further rotation, and It is preferable to press the TAS device onto the tube sheet with a target.
(Mode 7) It is preferable that the rising, lowering, and pressing on the tube plate in the TAS apparatus are performed hydraulically by a telescopic type (cylinder piston type) with a piston incorporated in the TAS nozzle.
(Embodiment 8) It is preferable that the rotation speed of the TAS nozzle of the TAS apparatus is uniquely adapted by a gear motor.
(Embodiment 9) It is preferable that the rotation in the TAS apparatus is performed by a water turbine attached to the water flow.
(Mode 10) It is preferable that a plurality of TAS devices are attached, and each TAS device is operated individually or simultaneously in time by a unique or joint drive unit.
(Mode 11) The TAS apparatus is preferably manufactured from a specific low friction material.
(Mode 12) It is preferable that local and short-term overheating is automatically and periodically performed and automatically monitored by using a built-in measurement system and control system and a regulator.
(Mode 13) In a sea chest cooler having six or more flow channels, it is preferable that a separate TAS device is arranged in each nozzle chamber or at least in each second nozzle chamber.
(Form 14) The TAS nozzle is preferably formed as individual radial circular segments, or as circular segments over the entire diameter, or using other circular segment shapes.

  In a sea chest cooler with a built-in thermal anti-fouling system (hereinafter referred to as “TAS”), the heat exchanger tube (or heat exchanger tube) has a generally circular or square (cross section) arrangement. Due to the new design of the tube bundle, the configuration, the individual circular segments (or circular components) of the tube bundle of the sea chest cooler (in the heat exchanger tubes) can be cooled or not during the cooling operation by mechanical TAS devices. A specific section is created that makes it possible to supply hot water. The TAS device has, for example, a nozzle that rotates with angular increments to follow a circular (cross-sectional) arrangement of heat exchanger tubes in a tube sheet (or tube sheet), whereby each For the section, attached organisms are killed in the vicinity of the outer wall of the tube and / or the tube bundle as a result of the periodic supply of heated water to the individual heat exchanger tubes or individual sections of the sea chest cooler.

  In this case, in particular, the cooling surface of the sea chest cooler needs to be appropriately enlarged in order to be able to release heat that is additionally taken into the system, preferably from the hot engine coolant circulation circuit (ME-HAT). However, this can often be adequately compensated for by reducing the fouling margin based on extremely clean coolers.

  An advantage of the present invention is that deposit protection of the sea chest cooler is possible without stopping the seacast cooler during continuous marine operation using the built-in TAS. If the berthing period is relatively long, deposit protection can be similarly performed during port operation via a separate preheater in the TAS circuit, such as an auxiliary or overproduction capacitor. A further advantageous side effect is that the low temperature circuit (ME-LT) can be preheated during port operation via this device, so that the main machine is always kept in operation. . Thus, traditional preheating units can be eliminated, which saves recurring energy costs and purchase costs.

  Examples according to the present invention will be described in detail below.

It is a figure which shows the sea chest cooler provided with the TAS apparatus 13 for deposit protection. FIG. 2 is a view showing a tube sheet 14 provided with a circular segment 15. It is an overhead view of the tube sheet 14. FIG. It is a figure which shows the path | route of the heating water in the state where the TAS nozzle 1 was lowered. It is side sectional drawing of the TAS apparatus 13 in which the TAS nozzle 1 was lowered | hung. It is a figure which shows the TAS apparatus 13 in which the TAS nozzle 1 was raised. It is a figure which shows the movement path | route of the TAS nozzle 1 at the time of TAS operation. It is a figure which shows the flowchart of the sea chest cooler with which TAS was incorporated.

  FIG. 1 a shows a sea chest cooler (or seabox cooler) 16 with main components such as a tube bundle (or tube bundle) 9, a lid 12 and a built-in TAS device 13. The engine cooling water flows through the inflow connecting pipe 2 and into the space of the sea chest cooler 16 formed by the lid portion 12 and the tube plate (tube attachment plate or tube plate) 14.

  1b and 1c show the structural aspect of the tube sheet 14 in which a plurality of U-shaped tubes are arranged in a circle (as viewed in cross section) and the tube sheet range in the center of the nozzle chamber 21 (FIG. 2). ing. The TAS nozzle 13 (or rotating nozzle) 1 (FIG. 2) (with the ability to move up and down) on the TAS device 13 (FIG. 2) operates properly with a target for the tube sheet range, thereby heat exchanger tubes. 20 (FIG. 2) is protected against deposits.

  As shown in FIG. 2, the heating water is directed to the TAS nozzle 1 via the rotation execution unit 6 via the TAS inflow portion 8 provided with the shut-off valve 10, and out of the heat exchanger tubes 20 of the tube bundle 9. A small number of heat exchanger tubes 20 flow to heat them. The rotation execution unit 6 seals the TAS device 13 outward (to the outside) with respect to the lid 12, and simultaneously sends TAS water (or heated water) to the TAS nozzle 1, and further the TAS nozzle 1 rotates. And axial vertical movement.

  3 and 4 are cross-sectional views of the lid portion 12, and the TAS nozzle 1 is shown in the lowered position (FIG. 3) and the raised position (FIG. 4). 3 and 4 illustrate an embedded TAS device 13 with a lift unit 4 (FIG. 2) according to the present invention. The lift unit 4 presses the shaft of the rotation execution unit 6 to cause the TAS nozzle 1 to rise, holds the TAS nozzle 1 in the raised position during further rotation to the next position, and after reaching the next position The TAS nozzle 1 is lowered and the pressing of the TAS nozzle 1 against the tube plate 14 is ensured, whereby the next circular segment (or circular component) of the heat exchanger tube 20 is heated. According to the present embodiment, the rotation drive unit 5 transmits torque to the shaft of the rotation execution unit 6 (or the rotation nozzle 1) by the belt 7.

  FIG. 5 shows a circular arrangement of a plurality of heat exchanger tubes 20 (as viewed in cross section). The TAS nozzle 1 rotates to follow the circular arrangement of the heat exchanger tubes 20 in the tube plate 14 with angular increments, thereby a special section that separates the heat exchanger tubes 20 from the actual cooling water. To produce. The TAS nozzle 1 supplies hot water to the circular segment 15 of the (predetermined) tube bundle 9 that is isolated (or partitioned) among the individual heat exchanger tubes 20. However, in the sea chest cooler 16 having six or more channels, a separate TAS device 13 is attached in each nozzle chamber 21 or at least in each second nozzle chamber 21. The TAS nozzle 1 can also be implemented in the radial direction, as shown in FIG. 5, over the entire diameter, or in the form of a circular segment.

  FIG. 6 shows a low temperature circulation circuit (ME-LT) for engine cooling water for heating a partial flow of engine cooling water and introducing it into the sea chest cooler 16 via a TAS inlet 8 with a shut-off valve 10. ) Shows the basic arrangement of components. Water is heated to a temperature level of at least 75 ° C. via temperature control valve 19. The valves 22 and 23 are opened via a control device depending on the temperature. Before that, the TAS nozzle 1 is lowered and the heated TAS water flows into the section partitioned by the TAS nozzle 1 to heat the heat exchanger tube 20 in the section. The whole TAS cycle takes place with angular increments, i.e. until the TAS nozzle 1 has finished performing a full circular movement of at least 360 °.

1 TAS nozzle (or rotating nozzle that can move up and down)
2 Connection pipe-for cooling water inflow 3 Connection pipe-for cooling water outflow 4 Lift unit 5 Rotation drive unit Nozzle 6 Rotation execution unit (Drehdurchfuehrung)
7 Belt 8 TAS inflow section Heating water 9 Tube bundle (or tube bundle)
10 shut-off valve 11 temperature sensor 12 cooler lid 13 TAS device 14 tube plate (or tube plate)
15 Circular segments (or circular components)
16 Sea chest cooler (or sea box cooler)
17 TAS circulation pump 18 TAS heat exchanger 19 TAS temperature control valve 20 heat exchanger tube (or heat exchanger tube)
21 Nozzle chamber 22 Valve-Outflow part For TAS water

Claims (8)

A sea chest cooler with a built-in fouling protection system to kill barnacles, shellfish and other fouling organisms by periodically repeatable overheating,
The sea chest cooler includes a tube bundle (9) having a plurality of heat exchanger tubes (20);
The deposit protection system is composed of a thermal anti-fouling TAS device (13),
At least one partial surfaces of the circular-shaped or square tube plate (14) is, due to the series connection of the inlet opening of the plurality of heat exchanger tubes of the second cooling circuit (20), a plurality of heat exchange in the first cooling circuit Formed by co-location with the outlet opening of the vessel tube (20), and thus provided with a nozzle chamber (21) in a coupled state with the cooler lid (12),
In the nozzle chamber (21), a TAS nozzle (1) capable of rotating the TAS device (13) is provided,
The TAS nozzle (1) is provided with individual circular segments (15) comprising a plurality of heat exchanger tubes (20) of the tube bundle (9) by mounting the tube plate (14) on the circular or square partial surface. ) covers, thus urging sealed the heat exchanger tube that is isolated by (20), by heating water to be supplied separately, during normal cooling operation or normal cooling operation outside of the seawater side to ambient Being protected against kimono , and
Due to the further rotation of the TAS device (13), a new circular segment (15) consisting of individual heat exchanger tubes (20) in the tube sheet (14) is covered by the TAS nozzle (1). A featured sea chest cooler. The TAS system rotation execution unit as part of (13) (6), and wherein the sealing water space of the cooler lid (12) outwardly, according to claim 1 Sea chest cooler with built-in deposit protection system. The TAS nozzle mounted before Symbol rotation execution unit (6) (1), and characterized in that the outer shape of the TAS nozzle (1) is adapted to one or more circular segments (15) A sea chest cooler comprising the built-in deposit protection system according to claim 2 . In addition, a lift unit (4) is mounted, which lifts the TAS nozzle (1) before each further rotation in the TAS device (13) and that further rotates. The built-in attachment according to any one of claims 1 to 3 , characterized in that it is lowered again after and the TAS nozzle ( 1 ) is set on a target and pressed onto the tube sheet (14). Sea chest cooler with kimono protection system. The ascent, descent, and pressing on the tube plate (14) in the TAS device (13) are performed telescopically and hydraulically by a piston incorporated in the TAS nozzle (1). A sea chest cooler comprising the built-in deposit protection system according to claim 4 . The sea chest cooler (16) having six or more channels is characterized in that a separate TAS device (13) is arranged in each nozzle chamber (21) or at least every other nozzle chamber (21). A sea chest cooler comprising the built-in deposit protection system according to any one of claims 1 to 5 . The TAS system is characterized in that it is operated temporally separately or simultaneously with inherent or joint drive unit per each (5), with an embedded deposit protection system according to claim 6 Sea chest cooler. The TAS nozzle (1) is formed over the radial direction, or over the entire diameter as viewed in the partial surface of the circle , or formed using a circular segment shape. A sea chest cooler comprising the built-in deposit protection system according to any one of claims 1 to 7 .

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