CN211642568U - Power circulation and propulsion system and underwater vehicle - Google Patents

Abstract

The utility model provides a power circulation and propulsion system and an underwater vehicle, wherein the power circulation and propulsion system comprises a power circulation module and a propulsion module connected with the power circulation module; the power cycle module comprises a cooling unit, a compression unit, a heat source generation unit and a turbine unit which are sequentially connected; the cooling unit is used for cooling the supercritical carbon dioxide entering the compression unit; the heat source generating unit is used for generating heat so that the supercritical carbon dioxide entering the heat source generating unit reaches the temperature of an inlet of the turbine unit within preset time, the turbine unit is connected with the propelling module, and the turbine unit is also connected with the cooling unit so that the supercritical carbon dioxide heated by the heat source generating unit does work through the turbine unit and is discharged to the cooling unit. The utility model provides a power cycle and propulsion system sets up to supercritical carbon dioxide through with the circulation medium, has reduced the circulation consumption, has improved the thermal efficiency.

Description

Power circulation and propulsion system and underwater vehicle

Technical Field

The utility model relates to an energy power and propulsion technical field especially relate to a power cycle and advancing system and underwater vehicle.

Background

The underwater vehicle is a navigation body navigating underwater, comprises a manned underwater vehicle and an unmanned underwater vehicle, and can complete underwater exploration, detection, even attack and defense in military and other tasks. At present, where ocean development is increasingly important, underwater vehicles are gaining more and more attention from various countries, playing an important role both in civilian use and military use. Given military and commercial interest, all countries around the world strive to explore and develop underwater vehicles, and unmanned underwater vehicles are an important development target.

At present, a closed turbine power system taking water vapor as a working medium is applied to an underwater vehicle, wherein superheated steam generated in a boiler reactor in the underwater vehicle is sent into a turbine to perform expansion work, a rotor rotates at a high speed, a speed reducer drives a propeller in the underwater vehicle to work after speed reduction, waste gas after expansion work is discharged into a shell condenser of the underwater vehicle, the generated waste gas is cooled and condensed into water through seawater outside the underwater vehicle in the condenser, the water is pressurized by a water supply pump and then is input into the boiler reactor to perform reheating work, and the operation is repeated, so that a closed circulation system in the whole process is formed. Therefore, reactants of the underwater vehicle of the closed turbine power system do not need to be discharged, no flight path, no exhaust noise and no pollution are generated during navigation, the power and the navigation speed are not influenced by back pressure, the number of control components is small, the overall performance is superior to that of a traditional three-component system, and the closed turbine power system is an ideal closed circulation system.

However, when the closed turbine system works circularly, two strands of seawater need to be introduced from the outside, one strand does work, the other strand cools, the system is complex, and the water working medium has multiple phase changes in the circulation, so that the power consumption is large, and the heat efficiency is low.

SUMMERY OF THE UTILITY MODEL

The utility model provides a power cycle and advancing system and underwater vehicle through setting up working medium into supercritical carbon dioxide, has reduced the circulation consumption, has improved the thermal efficiency.

In order to achieve the above object, the present invention provides a power circulation and propulsion system, comprising a power circulation module and a propulsion module connected to the power circulation module;

the power cycle module comprises a cooling unit, a compression unit, a heat source generation unit and a turbine unit which are sequentially connected; the cooling unit is used for cooling the supercritical carbon dioxide entering the compression unit; the heat source generating unit is used for generating heat so that the supercritical carbon dioxide entering the heat source generating unit reaches the temperature of an inlet of the turbine unit within preset time, the turbine unit is connected with the propelling module, and the turbine unit is also connected with the cooling unit so that the supercritical carbon dioxide heated by the heat source generating unit does work through the turbine unit and is discharged to the cooling unit.

As an alternative, the present invention provides a power cycle and propulsion system, wherein the propulsion module comprises an electric propulsion unit;

the electric propulsion unit comprises a motor generator, a first control switch connected with the output end of the motor generator, an electric load device and an electric propulsion assembly, wherein the first control switch can be selectively connected with the electric load assembly so as to enable the motor generator to provide electric energy for the electric load assembly; and/or the first control switch is selectively connectable with the electric propulsion assembly to cause the motor generator to provide electric energy to the electric propulsion assembly to generate thrust;

the input end of the motor generator is connected with the turbine unit.

As an optional mode, the utility model provides a power circulation and propulsion system, the propulsion module includes the thermal propulsion unit;

the thermal propulsion unit comprises a transmission device and an execution device, wherein the input end of the transmission device is connected with the turbine unit, the execution device is connected with the output end of the transmission device, and the transmission device is used for transmitting power for the execution device.

As an optional mode, in the power circulation and propulsion system provided by the present invention, the propulsion module further includes a motor generator and an electrical load assembly connected to the motor generator;

the motor generator is connected to the transmission and is configured to provide electrical power to the electrical load assembly.

As an optional mode, the power circulation and propulsion system provided by the present invention further includes a control unit and a thermal propulsion unit;

the thermal propulsion unit comprises a transmission device and an execution device, wherein the execution device is connected with the output end of the transmission device, and the transmission device is used for transmitting power for the execution device.

The input end of the control unit is connected with the turbine unit, and the output end of the control unit can be selectively connected with the electric propulsion unit or the thermal propulsion unit.

As an optional mode, in the power circulation and propulsion system provided by the present invention, the power circulation module further comprises a second control switch, and the second control switch is connected between the compression unit and the heat source generation unit;

the heat source generating unit comprises a first heat source assembly and a second heat source assembly, and if the second control switch is connected with the first heat source assembly, the control unit is connected with the electric propulsion unit; if the second control switch is connected with the second heat source assembly, the control unit is connected with the thermal propulsion unit.

As an alternative, the present invention provides a power cycle and propulsion system, wherein the transmission comprises a gear set, the actuator comprises a propeller, and the output end of the gear set is connected to the propeller.

As an optional mode, the utility model provides a power cycle and propulsion system, power cycle module still include the backheat unit, and the backheat unit has mutually independent first backheat passageway and second backheat the passageway, and compression unit and heat source generating element are connected with first backheat passageway, and turbine unit and cooling unit and second backheat the passageway and be connected.

As an optional mode, in the power circulation and propulsion system provided by the present invention, the electric propulsion assembly includes a motor control and drive structure, a motor and a propeller, which are connected in sequence; the first control switch is selectively connected with the motor control and drive structure, so that the motor provides electric energy for the propeller to enable the propeller to generate thrust.

The utility model also provides an underwater vehicle, including above-mentioned power cycle and advancing system.

The utility model provides a power circulation and propulsion system and an underwater vehicle, wherein the power circulation and propulsion system comprises a power circulation module and a propulsion module connected with the power circulation module; the power cycle module comprises a cooling unit, a compression unit, a heat source generation unit and a turbine unit which are sequentially connected; the cooling unit is used for cooling the supercritical carbon dioxide entering the compression unit; the heat source generating unit is used for generating heat so that the supercritical carbon dioxide entering the heat source generating unit reaches the temperature of an inlet of the turbine unit within preset time, the turbine unit is connected with the propelling module, and the turbine unit is also connected with the cooling unit so that the supercritical carbon dioxide heated by the heat source generating unit does work through the turbine unit and is discharged to the cooling unit. By setting the circulating medium to be supercritical carbon dioxide, the circulating power consumption is reduced, and the heat efficiency is improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a first schematic structural diagram of a power circulation and propulsion system according to an embodiment of the present invention;

fig. 2 is a schematic view of a second structure of a power circulation and propulsion system according to an embodiment of the present invention;

fig. 3 is a schematic view of a third structure of a power circulation and propulsion system according to an embodiment of the present invention;

fig. 4 is a schematic diagram illustrating a fourth structure of a power circulation and propulsion system according to an embodiment of the present invention;

fig. 5 is a schematic structural view of a power circulation and propulsion system according to a second embodiment of the present invention;

fig. 6 is a schematic structural view of a power circulation and propulsion system provided by a third embodiment of the present invention.

Description of reference numerals:

10-a power cycle module; 11-a cooling unit; 12-a compression unit; 13-a heat source generating unit; 131-a first heat source assembly; 132-a second heat source assembly; 14-a turbine unit; 15-a heat regenerative unit; 151-first recuperation channel; 152-a second regenerative channel; 16-a second control switch; 20-a propulsion module; 21-an electric propulsion unit; 211-a motor generator; 212-first control switch; 213-an electrical load assembly; 214-an electric propulsion assembly; 2141-motor control and drive architecture; 2142-an electric motor; 2143-propeller; 2144-motor generator start battery; 22-a thermal propulsion unit; 221-a transmission; 222-an execution device; 23-control unit.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the technical solutions in the embodiments of the present invention will be described in more detail below with reference to the drawings in the preferred embodiments of the present invention. In the drawings, the same or similar reference numerals denote the same or similar components or components having the same or similar functions throughout. The described embodiments are only some, but not all embodiments of the invention. The embodiments described below with reference to the drawings are exemplary and intended to be used for explaining the present invention, and should not be construed as limiting the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention. Embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

In the description of the present invention, it is to be noted that, unless otherwise expressly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning a fixed connection, an indirect connection through an intermediary, a connection between two elements, or an interactive relationship between two elements. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

The terms "first," "second," "third," "fourth," and the like in the description and in the claims of the present application and in the drawings described above, if any, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the application described herein are, for example, capable of operation in sequences other than those illustrated or otherwise described herein.

Supercritical carbon dioxide refers to a supercritical carbon dioxide fluid with temperature and pressure respectively higher than the critical temperature of 31.1 ℃ and the critical pressure of 7.38 MPa.

The supercritical carbon dioxide circulation system is a process of taking supercritical carbon dioxide as a circulation working medium, compressing, heating and expanding the supercritical carbon dioxide generally, effectively converting heat energy into mechanical energy, and converting the mechanical energy into electric energy through a generator, or converting the mechanical energy into the mechanical energy through a mechanical device.

Example one

Fig. 1 is a first schematic structural diagram of a power circulation and propulsion system according to an embodiment of the present invention; fig. 2 is a schematic view of a second structure of a power circulation and propulsion system according to an embodiment of the present invention; fig. 3 is a schematic view of a third structure of a power circulation and propulsion system according to an embodiment of the present invention; fig. 4 is a schematic diagram of a fourth structure of the power circulation and propulsion system according to the first embodiment of the present invention. As shown in fig. 1 to 4, an embodiment of the present invention provides a power circulation and propulsion system, including a power circulation module 10 and a propulsion module 20 connected to the power circulation module 10;

the power cycle module 10 comprises a cooling unit 11, a compression unit 12, a heat source generation unit 13 and a turbine unit 14 which are connected in sequence; the cooling unit 11 is used for cooling the supercritical carbon dioxide entering the compression unit 12; the heat source generating unit 13 is used for generating heat so that the supercritical carbon dioxide entering the heat source generating unit 13 reaches the temperature of the inlet of the turbine unit 14 within a preset time, the turbine unit 14 is connected with the propulsion module 20, and the turbine unit 14 is also connected with the cooling unit 11 so that the supercritical carbon dioxide heated by the heat source generating unit 13 is exhausted to the cooling unit 11 through the turbine unit 14;

compression unit 12, turbine unit 14 and propulsion module 20 are coaxially connected.

In particular, the cooling unit 11 can be a cooler, such as a dividing wall cooler, a shower cooler, a jacketed cooler and a coil cooler, a plate cooler, a shell and tube cooler, etc., or a condenser integrated with the hull of the underwater vehicle, etc.

Specifically, compression unit 12 can be the compressor, and wherein, the compressor is one kind and promotes the driven fluid machinery for high-pressure working medium with low pressure working medium the utility model discloses in the implementation, the compressor can be the axial-flow type compression, also can be radial compressor, or the compressor of other forms, to this, the embodiment of the utility model provides a do not limit.

Specifically, the turbine unit 14 mainly includes a turbine, wherein the turbine operates according to the following principle: a turbine is a machine for converting the capacity of a fluid medium into mechanical energy, and is also called a turbine, a turbine or a turbine, and the most important part of the turbine is a rotating element, namely a rotor or a wheel, which is mounted on a turbine shaft and has blades arranged uniformly along the circumference. The energy of the fluid is converted into kinetic energy when passing through the nozzle or the volute in the flow, and the fluid impacts the blades to push the impeller to rotate when passing through the impeller, so that the turbine shaft is driven to rotate, and the turbine shaft drives other machines to rotate directly or through a transmission mechanism to output mechanical work.

Wherein, the turbine can be axial-flow type turbine, also can be radial-flow type turbine, or the turbine of other forms, to this, the embodiment of the utility model provides a do not do the restriction.

Specifically, the heat source generating unit 13 heats the supercritical carbon dioxide to reach a temperature at an inlet of the turbine unit 14, so as to drive the turbine to rotate and output mechanical work. In the present embodiment, the heat source generating unit 13 includes the first heat source assembly 131, and the first heat source assembly 131 can provide relatively small heat for a long time.

Wherein, the source of heat source can be fossil energy, metal fuel, chemical fuel, waste heat etc. reaction heat in the navigation ware, to this, the embodiment of the utility model provides a do not do the restriction.

In the concrete implementation, in the power circulation process, the working medium supercritical carbon dioxide is always in a supercritical state, when the power circulation process is started, the motor generator 211 in the propulsion system is in a motor 2142 mode, the motor generator starts the battery 2144 to start the motor 2142 to rotate, and as the motor 2142 is coaxially connected with the turbine and the compressor, the compressor rotates, and the SCO heated by the first heat source component 131₂And then the gas enters the turbine unit 14 for isobaric expansion and outputs mechanical work, and the mechanical work is transmitted to a propulsion system, wherein the waste gas and the supercritical carbon dioxide generated in the expansion process of the turbine unit 14 enter the cooling unit 11 to enter the next cycle working process.

Further, the propulsion module 20 includes an electric propulsion unit 21, the electric propulsion unit 21 includes a motor generator 211, a first control switch 212 connected to an output of the motor generator 211, an electric load assembly 213, and an electric propulsion assembly 214, the first control switch 212 is selectively connected to the electric load assembly 213, so that the motor generator 211 provides electric energy to the electric load assembly 213; or the first control switch 212 may be selectively connected to the electric propulsion assembly 214 so that the motor generator 211 provides electric power to the electric propulsion assembly 214 to generate thrust, and the input of the motor generator 211 is connected to the turbine unit 14.

Optionally, the electric propulsion assembly 214 includes a motor control and drive structure 2141, an electric motor 2142, and a propeller 2143 connected in sequence, and the first control switch 212 is selectively connected to the motor control and drive structure 2141, so that the electric motor 2142 provides electric energy to the propeller 2143 to cause the propeller 2143 to generate thrust. The propellers 2143 may be single-rotor propellers 2143, or double-rotor propellers 2143.

Specifically, when the output power of the power cycle module 10 reaches a certain value (for example, when the output power is greater than the cycle power consumption), the motor generator 211 is switched to a generator mode, the motor generator starting battery 2144 is connected to the motor control and driving structure 2141, the first control switch 212 is connected to other power loads, a part of the electric energy generated by the generator flows through the motor 2142 to drive the propeller 2143 to generate thrust, and a part of the residual electric energy is transmitted to other power loads, so that the daily power consumption for starting battery charging, switching, power control and conversion equipment, lighting and the like solves the power consumption and charging requirements of other loads in the underwater vehicle, and the use requirements of the underwater vehicle in long range and long voyage are met, thereby achieving the purpose of comprehensive power application.

It should be noted that when the propeller 2143 rotates in a single direction, the generator uses the single-rotation propulsion motor 2142, and when the propeller 2143 rotates in two directions, the generator uses the double-rotation propulsion motor 2142, and the rotation directions of the double-rotation propeller 2143 are opposite, so that the balance of the underwater vehicle can be maintained when the underwater vehicle is underway, and the balance reliability of the underwater vehicle when the underwater vehicle is traveling is improved.

Further, the power cycle module 10 further includes a heat recovery unit 15, the heat recovery unit 15 has a first heat recovery channel 151 and a second heat recovery channel 152 that are independent of each other, the compression unit 12 and the heat source generation unit 13 are connected to the first heat recovery channel 151, and the turbine unit 14 and the cooling unit 11 are connected to the second heat recovery channel 152.

Specifically, regenerator unit 15 can be the regenerator, for example, can be attached formula regenerator, bushing type regenerator, shell-and-tube regenerator, printed circuit board heat exchanger etc. to this, the embodiment of the utility model provides a do not do the restriction.

The supercritical carbon dioxide absorbs a part of heat through the heat recovery unit 15 to raise the temperature, and further absorbs heat through the heat source generation unit 13 to reach the normal operating temperature of the turbine unit 14.

Furthermore, the compression unit 12 and the heat source generation unit 13 are connected with the first heat recovery channel 151, the turbine unit 14 and the cooling unit 11 are connected with the second heat recovery channel 152, because the temperature of the supercritical carbon dioxide is lower after the isothermal compression process, the waste heat temperature of the supercritical carbon dioxide is higher after the isothermal expansion process, the isobaric heating and the isobaric heat release are all performed in the heat regenerator, the circulation only has heat exchange with the outside during the isothermal compression and the isothermal expansion, the irreversible factor of temperature difference heat transfer is eliminated, and the pinch point problem of the heat regenerator can be effectively avoided.

Example two

Fig. 5 is a schematic structural view of a power circulation and propulsion system according to a second embodiment of the present invention. As shown in fig. 5, based on the above embodiment, in the power circulation and propulsion system provided in the embodiment of the present invention, optionally, the propulsion module 20 includes a thermal propulsion unit 22, the thermal propulsion unit 22 includes a transmission device 221 and an execution device 222, an input end of the transmission device 221 is connected to the turbine unit 14, the execution device 222 is connected to an output end of the transmission device 221, and the transmission device 221 is used for transmitting power to the execution device 222.

In particular, the transmission 221 may be a gear set, that is, the transmission 221 may be a gear box composed of a gear set, the actuator 222 may be a propeller 2143, and the propeller 2143 is connected to an output end of the gear box, so that the rotation speed of the propeller 2143 can be adjusted by the gear box.

Further, when the mechanical work transmitted from the turbine unit 14 pushes the propeller 2143 to generate a large power thrust through the transmission case and remains, the motor generator 211 may be coaxially connected to any gear in the gear set, so that the motor generator 211 is converted into a generator, and the remaining mechanical work is generated by the generator to supply a small amount of electric energy to other electric loads, and the motor generator 211 may be located on the same side as the propeller 2143 or on different sides, according to specific structural requirements and spatial arrangement, which is not limited in this embodiment.

In this embodiment, the heat source generating unit 13 includes the second heat source component 132, and the instantaneous heat generated by the reaction is relatively large, and the output power is relatively large, so that the use requirements of high power, high navigational speed, long range and large navigational depth can be met.

Wherein, the source of heat source can be fossil energy, metal fuel, chemical fuel, waste heat etc. reaction heat in the navigation ware, to this, the embodiment of the utility model provides a do not do the restriction. In a specific implementation, in a propulsion process of the propulsion module 20, an output shaft of the turbine unit 14 is directly connected to the gearbox, and each group of gears in the gearbox are in a meshed state, wherein most of shaft power output by the turbine unit 14 pushes the propeller 2143 through the gearbox to generate high-power thrust, and a small remaining part of mechanical power generates a small amount of electric energy through the motor generator 211 to supply electricity to other electric loads, so that comprehensive requirements of the underwater vehicle on high power, high speed, long range and large navigation depth can be met, and a purpose of thermal propulsion in a power cycle and propulsion system is achieved.

EXAMPLE III

Fig. 6 is a schematic structural view of a power circulation and propulsion system provided by a third embodiment of the present invention. As shown in fig. 6, on the basis of the first embodiment, optionally, the propulsion system further includes a control unit 23 and a thermal propulsion unit 22, where the thermal propulsion unit 22 includes a transmission device 221 and an actuating device 222, the actuating device 222 is connected to an output end of the transmission device 221, and the transmission device 221 is used for transmitting power to the actuating device 222;

the input of control unit 23 is connected to turbine unit 14, and the output of control unit 23 is optionally connected to electric propulsion unit 21 or to thermal propulsion unit 22.

Further, the power cycle module 10 further includes a second control switch 16, the second control switch 16 is connected between the compression unit 12 and the heat source generation unit 13, the heat source generation unit 13 includes a first heat source assembly 131 and a second heat source assembly 132, and if the second control switch 16 is connected to the second heat source assembly 132, the control unit 23 is connected to the thermal propulsion unit 22.

It should be noted that the instantaneous heat generated by the reaction of the second heat source component 132 is relatively large, and the output power is relatively large, so that the heat pump is suitable for being applied to occasions with short-time and high power; the first heat source assembly 131 generates a small amount of instantaneous heat during the reaction, but the duration of combustion is long, and thus, is suitable for long-term low-power applications.

In the embodiment, when the underwater vehicle cruises at a low speed, the second control switch 16 switches the heat source of the power cycle to the first heat source assembly 131 mode, the propulsion system switches to the circuit propulsion mode, the turbine unit 14 drives the electric generator 211 to generate electric energy, a part of the electric energy is converted into mechanical work to push the propeller 2143 to generate thrust, and a part of the electric energy is used for supplying power to other electric loads; when the underwater vehicle is cruising at a high speed, a heat source of power circulation is switched to a mode of a second heat source component 132 through a second control switch 16, a propulsion system is switched to a thermal propulsion mode, a control unit 23 drives a first-stage gear and a second-stage gear in a speed change gear box to be meshed, the second-stage gear and a third-stage gear are meshed and the like, at the moment, a turbine unit 14 directly drives the gear box to push a propeller 2143 to generate high-power thrust, a small amount of mechanical power is converted into a small amount of electric energy to supply electric power required by the underwater vehicle during cruising, and therefore medium-power and low-power electric propulsion is added into a power system mainly based on the high-power thermal propulsion, and the thermoelectric hybrid propulsion mode can be achieved.

Wherein the control unit 23 may be a clutch, for example: a gear change clutch, a friction clutch, and the like, and the present embodiment is not limited thereto.

Example four

The embodiment also provides an underwater vehicle which comprises the power circulation and propulsion system.

The structure and operation principle of the power cycle and propulsion system are explained in detail in the above embodiments, and are not described in detail in this embodiment.

The embodiment of the utility model provides an underwater vehicle, which comprises a power circulation and propulsion system, wherein the power circulation and propulsion system comprises a power circulation module and a propulsion module connected with the power circulation module; the power cycle module comprises a cooling unit, a compression unit, a heat source generation unit and a turbine unit which are sequentially connected; the cooling unit is used for cooling the supercritical carbon dioxide entering the compression unit; the heat source generating unit is used for generating heat so that the supercritical carbon dioxide entering the heat source generating unit reaches the temperature of an inlet of the turbine unit within preset time, the turbine unit is connected with the propelling module, and the turbine unit is also connected with the cooling unit so that the supercritical carbon dioxide heated by the heat source generating unit does work through the turbine unit and is discharged to the cooling unit. The circulating medium is set to be the supercritical carbon dioxide, so that the circulating power consumption is reduced, the heat efficiency is improved, and the system structure is simple.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.

Claims (10)

1. A power cycle and propulsion system comprising a power cycle module and a propulsion module connected to the power cycle module;

the power circulation module comprises a cooling unit, a compression unit, a heat source generation unit and a turbine unit which are sequentially connected; the cooling unit is used for cooling the supercritical carbon dioxide entering the compression unit; the heat source generating unit is used for generating heat so that the supercritical carbon dioxide entering the heat source generating unit reaches the temperature of the inlet of the turbine unit within a preset time, the turbine unit is connected with the propelling module, and the turbine unit is also connected with the cooling unit so that the supercritical carbon dioxide heated by the heat source generating unit does work through the turbine unit and is discharged to the cooling unit.

2. The power cycle and propulsion system of claim 1, wherein the propulsion module comprises an electric propulsion unit; the electric propulsion unit comprises a motor generator, a first control switch connected with the output end of the motor generator, an electric load assembly and an electric propulsion assembly, wherein the first control switch can be selectively connected with the electric load assembly so that the motor generator can provide electric energy for the electric load assembly; and/or the first control switch is selectively connectable with the electric propulsion assembly to cause the motor generator to provide electric energy to the electric propulsion assembly to generate thrust;

the input end of the motor generator is connected with the turbine unit.

3. The power cycle and propulsion system of claim 1, wherein the propulsion module comprises a thermal propulsion unit;

the thermal propulsion unit comprises a transmission device and an execution device, wherein the input end of the transmission device is connected with the turbine unit, the execution device is connected with the output end of the transmission device, and the transmission device is used for transmitting power for the execution device.

4. The power cycle and propulsion system of claim 3, wherein the propulsion module further comprises a motor-generator and an electrical load assembly connected to the motor-generator;

the motor generator is coupled to the transmission and is configured to generate electricity to provide electrical power to the electrical load assembly.

5. The power cycle and propulsion system of claim 2, wherein the propulsion module further comprises a control unit and a thermal propulsion unit;

the thermal propulsion unit comprises a transmission device and an execution device, the execution device is connected with the output end of the transmission device, and the transmission device is used for transmitting power to the execution device;

the input end of the control unit is connected with the turbine unit, and the output end of the control unit can be selectively connected with the electric propulsion unit or the thermal propulsion unit.

6. The power cycle and propulsion system of claim 5, wherein the power cycle module further comprises a second control switch connected between the compression unit and the heat source generation unit;

the heat source generating unit comprises a first heat source component (131) and a second heat source component (132), and if the second control switch is connected with the first heat source component (131), the control unit is connected with the electric propulsion unit; if the second control switch is connected to the second heat source assembly (132), the control unit is connected to the thermal propulsion unit.

7. The power cycle and propulsion system of any one of claims 3 to 6, wherein the transmission comprises a gear set and the implement comprises a propeller, an output of the gear set being connected to the propeller.

8. The power cycle and propulsion system of any one of claims 1 to 6, wherein the power cycle module further comprises a regenerative unit having first and second regenerative channels independent of each other, the compression unit and the heat source generation unit being connected to the first regenerative channel, and the turbine unit and the cooling unit being connected to the second regenerative channel.

9. The power cycle and propulsion system of claim 2, wherein the electric propulsion assembly comprises a motor control and drive structure, an electric motor and a propeller connected in series; the first control switch is selectively connectable with the motor control and drive structure to cause the motor to provide electrical power to the propeller to cause the propeller to generate thrust.

10. An underwater vehicle comprising a power cycle and propulsion system according to any of claims 1 to 9.

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