CN112803674A

CN112803674A - Marine generator cooling system

Info

Publication number: CN112803674A
Application number: CN202110040429.3A
Authority: CN
Inventors: 袁思鸣; 王磊; 陈科; 韩恩权; 肖汉华; 胡端; 祝剑
Original assignee: 92557 Troops Of Chinese Pla; Chinese People's Liberation Army 91776; Unit 91001 Of Chinese Pla; People's Liberation Army 92578; Beijing Institute of Electronic System Engineering
Current assignee: 92557 Troops Of Chinese Pla; Chinese People's Liberation Army 91776; Unit 91001 Of Chinese Pla; People's Liberation Army 92578; Beijing Institute of Electronic System Engineering
Priority date: 2021-01-13
Filing date: 2021-01-13
Publication date: 2021-05-14
Anticipated expiration: 2041-01-13
Also published as: CN112803674B

Abstract

The invention provides a heat dissipation system of a marine generator, which comprises a detection device, a supply device, a storage device, a supporting device and a processor, wherein the detection device is used for detecting a heat dissipation mechanism in the storage device; the supply device is configured to supply a heat dissipating liquid; the storage device is configured to store the detection device, the heat dissipation liquid, and the support device; the support device is configured to support the detection device. According to the invention, parameters such as temperature and the like in the storage device are detected by detecting in the storage device, and meanwhile, the atomization effect of the storage device on the gasification generator is adjusted based on the temperature, so that the heat dissipation effect of the heat dissipation mechanism is ensured to be performed in an excellent state; by adopting the drying tower configured to perform the operation of recovering the overheated heat dissipation liquid, it is ensured that the heat dissipation liquid can be recovered and reused.

Description

Marine generator cooling system

Technical Field

The invention relates to the technical field of generator heat dissipation, in particular to a heat dissipation system of a marine generator.

Background

The large-capacity generator is an important device of the overwater mobile nuclear power station, and the heat dissipation problem is the most critical for ensuring the long-term safe and reliable operation of the large-capacity generator in a ship cabin.

For example, CN207588643U prior art discloses a heat dissipation device for a large-capacity air-water-cooled generator for ships, in a cabin of a marine ship, if a natural air-cooling manner is adopted for heat dissipation, a corresponding air conditioning system must be configured, but the large-capacity generator normally operates with a heat generation amount of tens to hundreds of kilowatts, if the heat dissipation is completely dependent on the air conditioner, a great burden is imposed on the air conditioning system of the ship, and the implementation in engineering is difficult.

Another typical prior art disclosed in WO2017206715a1 discloses a power generation system based on thermal energy from the exhaust of a marine vessel main engine. Also, as shown in the prior art of WO2014096895a1, an engine device includes a waste heat recovery system having a descending heat storage device, exhaust gas from a main engine is directly discharged to cause a large amount of waste heat, and the waste heat of the main engine cannot be effectively utilized due to an increase in outside air temperature, so as to improve the utilization efficiency of fuel oil.

The invention aims to solve the problems that the heat dissipation is poor, equipment needs to be added, heat energy cannot be fully utilized, the cooling effect is poor and the like in the field.

Disclosure of Invention

The invention aims to provide a heat dissipation system of a marine generator, aiming at the defects of heat dissipation of the conventional generator.

In order to overcome the defects of the prior art, the invention adopts the following technical scheme:

a marine generator heat dissipation system, the heat dissipation system comprising a detection device, a supply device, a storage device, a support device, and a processor, the detection device configured to detect a heat dissipation mechanism in the storage device; the supply device is configured to supply a heat dissipating liquid; the storage device is configured to store the detection device, the heat dissipation liquid, and the support device; the support device is configured to support the detection device.

Optionally, the detection device comprises a plurality of detection rods, a plurality of spacer paper, a plurality of support rods, a detection seat support seat and a detection element, wherein the spacer paper is configured to be provided with a plurality of detection through holes and support through holes, one end of each detection rod penetrates through the through holes, the other end of each detection rod is connected with the detection seat, and the detection element is configured to detect each detection rod; the partition paper is also configured to be equally spaced apart, and each of the support bars is configured to support the partition paper.

Optionally, the supply device comprises a desalination mechanism and a supply mechanism, wherein the desalination mechanism is configured to desalinate seawater and supply the seawater to the storage device through the supply mechanism; the desalination mechanism comprises a housing provided with a chamber, a delivery conduit configured to be disposed within the chamber, a hydrophobic membrane configured to be disposed within the chamber, and a cavity formed by the hydrophobic membrane disposed on a tube side of the housing, and a cavity volume outside of the hollow fibers and the delivery conduit forming a shell side of the chamber; the supply mechanism is configured to supply seawater into the shell side of the chamber.

Optionally, the storage device includes a circulation pipe and a heat conducting member, a reaction cavity is provided on a pipe wall of the circulation pipe, the heat conducting member is configured to be disposed on the heat conducting member and dissipate heat of the heat conducting member, and the heat conducting member is configured to be detachably connected to the circulation pipe; two ends of the circulating conduit are respectively connected with the supply device to form a circulating loop; the inner wall of the circulation pipe is configured to be provided with the detection unit configured to detect a parameter in the circulation pipe.

Optionally, the supporting device includes a supporting seat and a supporting frame configured to be disposed on the supporting seat and support the detecting device and the supplying device.

Optionally, the desalination mechanism further comprises a sealing member, a side hole, a first air chamber and a second air chamber, wherein the sealing member is configured to fix the end of the hydrophobic membrane and form a sealing end on the shell side of the chamber; the side hole is arranged in the shell and is communicated with the shell side of the chamber, and the side hole is arranged between two sealing ends; a first tube side port in the housing opens into a first plenum that is in fluid communication with the tube side of the chamber through a first plenum; a second tube side port in the housing opens into a second plenum that is in fluid communication with the tube side of the chamber through a second tank.

The beneficial effects obtained by the invention are as follows:

1. the supporting rods are used for supporting the spacing paper, so that the spacing between the spacing paper is always kept, and the heat dissipation process can be more efficient;

2. the water mist generator is also connected with the supply device, so that the heat dissipation mechanism can be ensured to always keep a high-efficiency heat dissipation effect in the process of supplying the heat dissipation liquid by the supply device;

3. the seawater can be extracted according to actual requirements when the ship sails by the desalination operation of the desalination mechanism, and the whole generator is rapidly cooled based on the desalination operation of the desalination mechanism;

4. detecting parameters such as temperature in the storage device by detecting in the storage device, and adjusting the atomization effect of the gasification generator by the storage device based on the temperature to ensure that the heat dissipation effect of the heat dissipation mechanism is performed in an excellent state;

5. by adopting the drying tower configured to perform the operation of recovering the overheated heat dissipation liquid, it is ensured that the heat dissipation liquid can be recovered and reused.

Drawings

The invention will be further understood from the following description in conjunction with the accompanying drawings. The components in the figures are not necessarily to scale, emphasis instead being placed upon illustrating the principles of the embodiments. Like reference numerals designate corresponding parts throughout the different views.

Fig. 1 is a schematic structural view of the heat-conducting member and the spacer paper.

Fig. 2 is a right-side schematic view of the detection rod and the spacer paper.

Fig. 3 is a schematic structural view of the detection rod and the support seat.

Fig. 4 is an enlarged schematic structural diagram of the point a.

Fig. 5 is a schematic structural diagram of the desalination mechanism.

The reference numbers illustrate: 1-a support bar; 2-detecting the through hole; 3-a detection rod; 4-spacer paper; 5-a heat conducting member; 6-detecting the seat; 7-a pressure block; 8-a detection element; 9-a delivery catheter; 10-shell.

Detailed Description

In order to make the objects and advantages of the present invention more apparent, the present invention will be further described in detail with reference to the following embodiments; it should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention. Other systems, methods, and/or features of the present embodiments will become apparent to those skilled in the art upon review of the following detailed description. It is intended that all such additional systems, methods, features and advantages be included within this description, be within the scope of the invention, and be protected by the accompanying claims. Additional features of the disclosed embodiments are described in, and will be apparent from, the detailed description that follows.

The same or similar reference numerals in the drawings of the embodiments of the present invention correspond to the same or similar components; in the description of the present invention, it should be understood that if there is an orientation or positional relationship indicated by the terms "upper" and "lower" and "left" and "right" etc., it is only for convenience of description and simplification of the description based on the orientation or positional relationship shown in the drawings, but it is not indicated or implied that the device or assembly referred to must have a specific orientation.

The first embodiment is as follows: a marine generator heat dissipation system, the heat dissipation system comprising a detection device, a supply device, a storage device, a support device, and a processor, the detection device configured to detect a heat dissipation mechanism in the storage device; the supply device is configured to supply a heat dissipating liquid; the storage device is configured to store the detection device, the heat dissipation liquid, and the support device; the supporting device is configured to support the detecting device; the detection device comprises a plurality of detection rods 3, a plurality of spacer paper 4, a plurality of support rods 1, a detection seat 6 and a detection element 8, wherein the spacer paper 4 is constructed to be provided with a plurality of detection through holes 2 and support through holes, one end of each detection rod 3 penetrates through the through holes, the other end of each detection rod 3 is connected with the detection seat 6, and the detection element 8 is constructed to detect each detection rod 3; the partition papers 4 are also configured to be distributed at equal intervals, and each of the support bars 1 is configured to support the partition papers 4; the supply device comprises a desalination mechanism and a supply mechanism, wherein the desalination mechanism is configured to desalinate seawater and supply the seawater to the storage device through the supply mechanism; the desalination mechanism comprises a housing 10, a delivery conduit 9, a hydrophobic membrane, the housing 10 being provided with a chamber, the delivery conduit 9 being configured to be disposed within the chamber, the hydrophobic membrane being configured to be disposed within the chamber, and the hydrophobic membrane forming a cavity disposed on the tube side of the housing 10, and the volume of the chamber outside the hollow fibers and the delivery conduit 9 forming the shell side of the chamber; the supply mechanism is configured to supply seawater into a shell side of the chamber; the storage device comprises a circulating pipeline and a heat conducting member 5, a reaction cavity is arranged on the pipe wall of the circulating pipeline, the heat conducting member 5 is configured to be arranged on the heat conducting member 5 and conduct heat dissipation on the heat of the heat conducting member 5, and the heat conducting member 5 is configured to be detachably connected with the circulating pipeline; two ends of the circulating conduit are respectively connected with the supply device to form a circulating loop; the inner wall of the circulating pipeline is configured to be provided with the detection unit, and the detection unit is configured to detect and detect parameters in the circulating pipeline; the supporting device comprises a supporting seat and a supporting frame, wherein the supporting frame is configured to be arranged on the supporting seat and support the detecting device and the supplying device; the desalination mechanism further comprises a sealing member, a side hole, a first air chamber and a second air chamber, wherein the sealing member is configured to fix the end part of the hydrophobic membrane and form a sealing end on the shell side of the chamber; the side hole is provided in the housing 10 and opens to the housing 10 side of the chamber, the side hole being provided between the two sealed ends; a first tube side port in the housing 10 opens into a first plenum that is in fluid communication with the tube side of the chamber through a first tank; a second tube side port in the housing 10 leads to a second plenum that is in fluid communication with the tube side of the chamber through a second tank.

Example two: the present embodiment should be understood to include at least all the features of any one of the embodiments described above and further improve upon the same, and in particular, to provide a heat dissipation system for a marine generator, the heat dissipation system including a detection device, a supply device, a storage device, a support device, and a processor, the detection device being configured to detect a heat dissipation mechanism in the storage device; the supply device is configured to supply a heat dissipating liquid; the storage device is configured to store the detection device, the heat dissipation liquid, and the support device; the supporting device is configured to support the detecting device; in particular, the detection device is used in cooperation with the supply device, so that the detection device can detect the supply operation of the supply device in the detection process, and in the supply device, the detected parameters comprise: flow, temperature, salinity, humidity and other parameters; in the present embodiment, the detection means is further configured to detect the inside of the storage means, that is: detecting parameters such as capacity, temperature and the like of the storage device; in addition, in this embodiment, the supporting device is configured to support the detecting device, so as to ensure that the detecting device can more accurately detect parameters of the storage device and the supplying device during a detection process; the heat dissipation mechanism of the generator comprises a heat dissipation seat and a heat dissipation plate, the heat dissipation seat and the heat dissipation plate are respectively arranged in the storage device, and the heat dissipation mechanism is subjected to heat dissipation operation through the operation of the detection device and the reaction device; in this embodiment, the heat dissipation liquid adopted by the heat dissipation mechanism adopts water to perform heat dissipation operation;

the detection device comprises a plurality of detection rods 3, a plurality of spacer paper 4, a plurality of support rods 1, a detection seat 6 and a detection element 8, wherein the spacer paper 4 is constructed to be provided with a plurality of detection through holes 2 and support through holes, one end of each detection rod 3 penetrates through the through holes, the other end of each detection rod 3 is connected with the detection seat 6, and the detection element 8 is constructed to detect each detection rod 3; the partition papers 4 are also configured to be distributed at equal intervals, and each of the support bars 1 is configured to support the partition papers 4; specifically, the detection device is arranged in the storage device and performs a heat dissipation operation on a heat dissipation mechanism in the storage device, in this embodiment, the detection operation of each detection rod 3 of the detection device on the partition paper 4 ensures that the partition paper 4 has a rapid cooling effect in the heat dissipation operation on the heat dissipation mechanism; in the present embodiment, the partition paper 4 is also configured to be replaceable or replaceable; in the embodiment, the detection rod 3 penetrates through the detection through hole 2 of the partition paper 4 and is used for detecting the partition paper 4; in this embodiment, when each detection rod 3 is pressed by each piece of partition paper 4, a replacement signal is triggered, and an operator can replace the partition paper 4; in this embodiment, each support rod 1 is used for supporting the partition paper 4, so that a space is always kept between the partition papers 4, and the heat dissipation process can be more efficient; in this embodiment, the detection rod 3 is connected with the detection seat 6, so that the detection rod 3 can be always positioned inside the detection through hole 2, and the heat dissipation efficiency of each piece of partition paper 4 to the heat dissipation mechanism can be ensured to achieve the best effect; in the present embodiment, water mist is provided between the partition papers 4, and the water mist is provided between the partition papers 4 and is continuously supplied; further, the water mist is supplied by a gasification generator configured to emit the water mist so that a heat radiation effect of the heat radiation mechanism is in an optimal state; the water mist generator is also connected with the supply device, so that the heat dissipation mechanism can be ensured to always keep a high-efficiency heat dissipation effect in the process of supplying the heat dissipation liquid by the supply device; in this embodiment, the water mist generator includes a pressure pump, a connection pipeline, and a control valve, where the connection pipeline is used to connect the control valve and the pump, so as to ensure efficient heat dissipation effect of the heat dissipation liquid; in addition, the control valve is also connected with the processor, and the control valve is ensured to control the spraying time and the spraying amount of the water mist under the control operation of the processor; in addition, the pressure pump is configured to pump the heat dissipation liquid in the pipe, so that the pressure flow in the connecting pipe is always kept in a constant range, the water mist wall sprayed between the partition papers 4 can be always kept in a constant state, and the heat dissipation effect of the heat dissipation device is further ensured; in addition, in the present embodiment, one end of each connecting rod, which is close to the detection seat 6, is provided with a pressure block 7, and the pressure element is arranged between each pressure block 7 and the detection seat 6; one side of each pressure block 7, which is close to each detection rod 3, is fixedly connected with each detection rod 3, one side of each pressure block 7, which is close to the support seat, is provided with a pressure hole, each detection element 8 is configured to be arranged in the pressure hole, and when each detection rod 3 bears pressure, each pressure block 7 bears the pressure and performs an extrusion operation on the detection element 8, at this time, the detection element 8 receives the extrusion and triggers the detection effect; in the present embodiment, the detection element 8 includes, but is not limited to, the following enumerated several cases: pressure sensors, gravity sensors, etc.;

the supply device comprises a desalination mechanism and a supply mechanism, wherein the desalination mechanism is configured to desalinate seawater and supply the seawater to the storage device through the supply mechanism; the desalination mechanism comprises a housing 10, a delivery conduit 9, a hydrophobic membrane, the housing 10 being provided with a chamber, the delivery conduit 9 being configured to be disposed within the chamber, the hydrophobic membrane being configured to be disposed within the chamber, and the hydrophobic membrane forming a cavity disposed on the tube side of the housing 10, and the volume of the chamber outside the hollow fibers and the delivery conduit 9 forming the shell side of the chamber; the supply mechanism is configured to supply seawater into a shell side of the chamber; specifically, the desalination mechanism further comprises a sealing member, a side hole, a first air chamber and a second air chamber, wherein the sealing member is configured to fix the end part of the hydrophobic membrane and form a sealing end on the shell side of the chamber; the side hole is provided in the housing 10 and opens to the housing 10 side of the chamber, the side hole being provided between the two sealed ends; a first tube side port in the housing 10 opens into a first plenum that is in fluid communication with the tube side of the chamber through a first tank; a second tube side port in the housing 10 leads to a second plenum that is in fluid communication with the tube side of the chamber through a second tank; specifically, the heat-dissipating liquid is supplied to the tube side of the housing 10 through one of the first tube side port and the second tube side port, and seawater is supplied to the shell side of the chamber through the outlet of the delivery pipe; the membrane separates a tube side of the chamber from a shell side of the chamber; the seawater is passed across the hydrophobic membrane in a radially cross-flow manner such that desalinated water vapor passes through the membrane to the tube side of the chamber; the delivery conduit 9 extends axially through the chamber to define a port of the delivery conduit 9 and includes a second inlet to the lumen of the delivery conduit 9, the second inlet being external to the chamber and adjacent the second end; a first end of the delivery conduit, wherein the first inlet is positioned proximate the first end of the delivery conduit; feeding seawater into both the first and second inlets of the transfer pipe and through the outlet of the transfer pipe; said delivery duct extends axially through said first and second ends of said housing 10; the delivery conduit includes a closed end axially opposite a first end of the delivery conduit adjacent which is an inlet to the lumen of the delivery conduit; a fill rate of the plurality of hydrophobic membranes in the chamber is less than 0.25; the surface area of the hydrophobic membrane per unit volume in the chamber matches the cavity; the seawater can be extracted according to actual requirements when the ship sails by the desalination operation of the desalination mechanism, and the whole generator is rapidly cooled based on the desalination operation of the desalination mechanism;

the storage device comprises a circulating pipeline and a heat conducting member 5, a reaction cavity is arranged on the pipe wall of the circulating pipeline, the heat conducting member 5 is configured to be arranged on the heat conducting member 5 and conduct heat dissipation on the heat of the heat conducting member 5, and the heat conducting member 5 is configured to be detachably connected with the circulating pipeline; two ends of the circulating conduit are respectively connected with the supply device to form a circulating loop; the inner wall of the circulating pipeline is configured to be provided with the detection unit, and the detection unit is configured to detect and detect parameters in the circulating pipeline; specifically, the storage device is used for storing the detection device and the supply device, and in the present embodiment, the detection device is disposed inside the storage device, and the heat conduction member 5 in the storage device is disposed between the partition sheets 4 of the detection device, so as to perform an operation of cooling the temperature of the heat conduction member 5; in this embodiment, the detection device is further configured to detect the inside of the storage device, detect parameters such as temperature in the storage device, and adjust the atomization effect of the gasification generator by the storage device based on the temperature, so as to ensure that the heat dissipation effect of the heat dissipation mechanism is performed in an excellent state; the circulation loop is provided with a discharge opening for storing or discharging materials, the discharge opening is connected with a recovery unit, the recovery unit comprises an airing tower, and the airing tower is configured to recover overheated heat dissipation liquid, so that the heat dissipation liquid can be recovered and reused; in the present embodiment, a detection means for detecting configured to detect the temperature in the airing tower and connected with the circulation duct through a connection duct is provided in the recovery unit; through the arrangement of the circulating pipeline, the heat conducting member 5 and the recovery unit, the heat dissipation process can be accurately controlled; also, in this embodiment, the storage device further comprises a plurality of heat exchanger plates arranged in a consecutive order, thereby forming first plate interspaces and second plate interspaces in an alternating order in the plate package, each first plate interspace defining an evaporation section for evaporation feed, the evaporation section extending in a longitudinal direction between an upper boundary fluidly connecting the evaporation section to the first separation section and a lower boundary sealing the opposite heat exchanger plates together, the evaporation section further extending in a transverse direction between a first side boundary and a second side boundary where the side boundaries of the opposite heat exchanger plates are sealed together, the evaporation section defining: a feed inlet located near the lower boundary for introducing feed in liquid form into the evaporation section, a heat exchange zone near the upper Border or, the heat exchange zone being formed by projections and recesses in the opposed heat exchange plates, the projections and recesses being arranged such that the opposed projections of the opposed heat exchange plates abut each other, a channel being located between the lower boundary and the heat exchange zone and from the feed inlet in the transverse direction for receiving feed from the feed inlet and allowing a uniform distribution of feed over the heat exchange zone, and a transition zone separating the heat exchange zone and the channel, the distance of the heat exchange zone in the transition zone of the maximum distance between the opposed heat exchange plates being smaller than the maximum distance between the opposed heat exchange plates in the channel and in the heat exchange zone; a maximum distance between opposing heat exchanger plates in the transition region is between 10% and 45% of a maximum distance between opposing heat exchanger plates in the channel; the supporting device comprises a supporting seat and a supporting frame, wherein the supporting frame is configured to be arranged on the supporting seat and support the detecting device and the supplying device; specifically, the supporting seat is fixedly connected with the supporting frame, so that the supporting device can be adjusted according to actual needs in the process of supporting the detection device and the supply device, the detection effect of the detection device is ensured, and meanwhile, the efficient supply of the heat dissipation liquid by the supply device is considered; in this embodiment, the heat dissipation liquid is preferably treated with the treated seawater.

Example three: this embodiment, which should be understood to include at least all the features of any one of the above embodiments and further improve on the same, specifically, provides an analysis algorithm for the heat dissipation temperature, wherein the analysis algorithm comprises the steps of obtaining the detected parameters from the gasification pump, the circulation pipeline and the desalination mechanism, and calculating according to the following formula (1):

wherein Xi is the supply speed, S is the initial liquid level position, v is the pumping speed;

and (3) obtaining the area with concentrated heat of the circulating pipeline through the formula, and carrying out modeling and gridding analysis on the area by a finite element analysis device: specifically, in this embodiment, the circulation track and the conduction member are modeled based on a temperature curve, and the supply speed, the initial position and the pumping speed are used for detection, and when the function value is deviated from the set value, the formula is used for adjustment, so as to effectively ensure the accuracy of the temperature control.

In the above embodiments, the descriptions of the respective embodiments have respective emphasis, and reference may be made to the related descriptions of other embodiments for parts that are not described or illustrated in a certain embodiment.

In summary, according to the heat dissipation system of the marine generator, the support rods are used for supporting the spacing paper, so that the spacing between the spacing paper is always kept, and the heat dissipation process can be more efficient; the water mist generator is also connected with the supply device, so that the heat dissipation mechanism can be ensured to always keep a high-efficiency heat dissipation effect in the process of supplying the heat dissipation liquid by the supply device; the seawater can be extracted according to actual requirements when the ship sails by the desalination operation of the desalination mechanism, and the whole generator is rapidly cooled based on the desalination operation of the desalination mechanism; detecting parameters such as temperature in the storage device by detecting in the storage device, and adjusting the atomization effect of the gasification generator by the storage device based on the temperature to ensure that the heat dissipation effect of the heat dissipation mechanism is performed in an excellent state; by adopting the drying tower configured to perform the operation of recovering the overheated heat dissipation liquid, it is ensured that the heat dissipation liquid can be recovered and reused.

Although the invention has been described above with reference to various embodiments, it should be understood that many changes and modifications may be made without departing from the scope of the invention. That is, the methods, systems, and devices discussed above are examples. Various configurations may omit, substitute, or add various procedures or components as appropriate. For example, in alternative configurations, the methods may be performed in an order different than that described, and/or various components may be added, omitted, and/or combined. Moreover, features described with respect to certain configurations may be combined in various other configurations, as different aspects and elements of the configurations may be combined in a similar manner. Further, elements therein may be updated as technology evolves, i.e., many elements are examples and do not limit the scope of the disclosure or claims.

Specific details are given in the description to provide a thorough understanding of the exemplary configurations including implementations. However, configurations may be practiced without these specific details, for example, well-known circuits, processes, algorithms, structures, and techniques have been shown without unnecessary detail in order to avoid obscuring the configurations. This description provides example configurations only, and does not limit the scope, applicability, or configuration of the claims. Rather, the foregoing description of the configurations will provide those skilled in the art with an enabling description for implementing the described techniques. Various changes may be made in the function and arrangement of elements without departing from the spirit or scope of the disclosure.

In conclusion, it is intended that the foregoing detailed description be regarded as illustrative rather than limiting, and that it be understood that these examples are illustrative only and are not intended to limit the scope of the invention. After reading the description of the invention, the skilled person can make various changes or modifications to the invention, and these equivalent changes and modifications also fall into the scope of the invention defined by the claims.

Claims

1. A heat dissipation system for a marine generator, the heat dissipation system comprising a detection device, a supply device, a storage device, a support device, and a processor, the detection device configured to detect a heat dissipation mechanism in the storage device; the supply device is configured to supply a heat dissipating liquid; the storage device is configured to store the detection device, the heat dissipation liquid, and the support device; the support device is configured to support the detection device.

2. The heat dissipating system of a marine generator according to claim 1, wherein the detecting means comprises a plurality of detecting rods, a plurality of spacer paper, a plurality of support rods, a detecting seat support, and a detecting element, the spacer paper is configured to have a plurality of detecting through holes and support through holes, one end of each of the detecting rods passes through the through holes, the other end of each of the detecting rods is connected to the detecting seat, and the detecting element is configured to detect each of the detecting rods; the partition paper is also configured to be equally spaced apart, and each of the support bars is configured to support the partition paper.

3. The marine generator heat dissipation system of any one of the preceding claims, wherein the supply device comprises a desalination mechanism and a supply mechanism, the desalination mechanism being configured to desalinate seawater and to supply the storage device via the supply mechanism; the desalination mechanism comprises a housing provided with a chamber, a delivery conduit configured to be disposed within the chamber, a hydrophobic membrane configured to be disposed within the chamber, and a cavity formed by the hydrophobic membrane disposed on a tube side of the housing, and a cavity volume outside of the hollow fibers and the delivery conduit forming a shell side of the chamber; the supply mechanism is configured to supply seawater into the shell side of the chamber.

4. The heat dissipating system of a marine generator of any of the preceding claims, wherein the storage device comprises a circulation pipe and a heat conducting member, a reaction chamber is provided on a wall of the circulation pipe, the heat conducting member is configured to be disposed on the heat conducting member and dissipate heat of the heat conducting member, and the heat conducting member is configured to be detachably connected to the circulation pipe; two ends of the circulating conduit are respectively connected with the supply device to form a circulating loop; the inner wall of the circulation pipe is configured to be provided with the detection unit configured to detect a parameter in the circulation pipe.

5. The marine generator heat dissipation system of any one of the preceding claims, wherein the support device comprises a support base and a support frame configured to be disposed on the support base and to support the detection device and the supply device.

6. The marine generator heat dissipation system of any one of the preceding claims, wherein the desalination mechanism further comprises a seal, side holes, a first air chamber and a second air chamber, the seal being configured to secure an end of the hydrophobic membrane and form a sealed end at a shell side of the chamber; the side hole is arranged in the shell and is communicated with the shell side of the chamber, and the side hole is arranged between two sealing ends; a first tube side port in the housing opens into a first plenum that is in fluid communication with the tube side of the chamber through a first plenum; a second tube side port in the housing opens into a second plenum that is in fluid communication with the tube side of the chamber through a second tank.