CN212332947U - Diesel-electric hybrid electric propulsion system for ship alternating current-direct current networking - Google Patents

Abstract

The invention discloses a diesel-electric hybrid electric propulsion system for ship alternating current-direct current networking, which comprises: the system comprises a diesel generator set, a storage battery set, a super capacitor set, an active rectifier, a variable/fixed frequency inverter, a bidirectional DC-DC unit, an alternating current bus, a direct current bus, a daily power transformer and a shore power interface; the diesel generating set is connected with an alternating current bus by a switch controlled by a parallel controller, each section of alternating current bus is connected by a switch bus, the alternating current bus is connected with a direct current bus by an active rectifier, each section of direct current bus is connected by the switch bus, the direct current bus is connected with a storage battery by a bidirectional DC-DC unit, a super capacitor set is connected with the direct current bus by the bidirectional DC-DC unit, the direct current bus is connected with a propulsion motor by a variable frequency inverter, the upper end of a daily power supply transformer is switched by two switches and is connected with the alternating current bus or a fixed frequency inverter, and the lower end of the daily power supply transformer is connected with a daily load of a ship.

Description

Diesel-electric hybrid electric propulsion system for ship alternating current-direct current networking

Technical Field

The utility model relates to a be applied to boats and ships power propulsion system, in particular to diesel generating set and power battery hybrid propulsion system of boats and ships alternating current-direct current network deployment.

Background

In ship engineering, a traditional propulsion system generally adopts a diesel engine as a prime mover, the propulsion system consists of the diesel engine, a reduction gear box, a shafting and a propeller, a shaft of the diesel engine is connected with the propeller shaft through the reduction gear box, the whole shafting occupies most space of a cabin, vibration and noise are strong, when ship load changes greatly, the diesel engine cannot change rapidly along with the change, so that the operation condition of the diesel engine is worsened, and oil consumption is increased.

With the development of the technology, an alternating current networking electric propulsion system for the ship appears, so that the layout space of a ship shafting is saved, and the electric driving response speed and the operability of the ship are improved. The ship alternating-current networking electric propulsion system is characterized in that each diesel engine drives a synchronous generator to generate electricity, alternating current with constant frequency and constant voltage is generated to carry out synchronous parallel operation or disconnection, an alternating-current distribution panel carries out alternating-current networking to establish a ship alternating-current power grid, the ship alternating-current power grid is distributed to an alternating-current-direct-alternating frequency converter, the alternating-current-direct-alternating frequency converter drives a ship propulsion motor, and the propulsion motor drives a ship propeller to propel a ship to run. When the ship load changes, the load power changes are adapted through synchronous parallel operation or disconnection of the diesel generating sets, and the method is a nonlinear switching mode. The ship alternating current networking mode can enable the diesel engine to operate at the optimal power efficiency point when the ship is propelled by economical cruising, and can cause the diesel engine not to operate at the optimal power efficiency point when the ship is propelled at low load and low speed, and the ship alternating current networking mode has the characteristics of maturity, reliability and compaction.

In recent years, a direct-current networking electric propulsion system appears, each generator set on a ship is connected with a rectifier, rectified direct current is connected to a common direct-current bus, a plurality of inverters are connected to the common direct-current bus in parallel, each inverter is connected with a propulsion motor, and each propulsion motor is connected with a ship propeller. When the load of the ship changes, the rotating speed of each diesel engine can be continuously and dynamically adjusted, so that the diesel engines run at the optimal fuel consumption point, the variable-speed running of the diesel engines is realized, and the fuel consumption of the diesel engines is reduced.

Disclosure of Invention

The utility model provides a to above-mentioned technical problem, provide a boats and ships alternating current-direct current network deployment's firewood electricity hybrid electric propulsion system, be a high redundancy, pursue the fail safe nature of boats and ships operation and the energy-conserving economic nature's of boats and ships operation technical problem.

The technical scheme is that the method achieves the purpose.

A diesel-electric hybrid electric propulsion system for ship AC-DC networking comprises: a diesel generator set, b diesel generator set, c diesel generator set and d diesel generator set, AC bus, a active rectifier, b active rectifier, c active rectifier, d active rectifier, e active rectifier and f active rectifier, a bidirectional DC-DC unit, b bidirectional DC-DC unit, c bidirectional DC-DC unit, d bidirectional DC-DC unit, e bidirectional DC-DC unit and f bidirectional DC-DC unit, a storage battery and b storage battery, a daily power transformer and b daily power transformer, a daily load and b daily load, a fixed frequency inverter and b fixed frequency inverter, DC bus, a variable frequency inverter and b variable frequency inverter and c variable frequency inverter and d variable frequency inverter, a main propulsion motor and b side propulsion motor and c side propulsion motor and d main propulsion motor, the super capacitor group a and the super capacitor group b are connected with the super capacitor group c and the super capacitor group d, and the shore power interface a and the shore power interface b.

The system comprises a diesel generating set a, a diesel generating set b, a diesel generating set c and a diesel generating set d, wherein each diesel generating set consists of a synchronous generating set and a switch controlled by a parallel controller, and each parallel controller is configured and connected with an alternating current bus through the switch controlled by the parallel controller. Wherein: the main diesel generator set is connected with the bus a, the diesel generator set b is connected with the bus b, the diesel generator set c is connected with the bus c, and the main diesel generator set d is connected with the bus d. In the alternating current mode, all the generator sets are synchronously connected into or disconnected from an alternating current bus through a switch controlled by a parallel controller. And in the direct current mode, each generator set operates at an independent speed regulation mode.

The alternating current bus includes: a bus bar, b bus bar, c bus bar, d bus bar, a switch, b switch and c switch.

The active rectifier a, the active rectifier b, the active rectifier c, the active rectifier d, the active rectifier e and the active rectifier f are all composed of LC filters and AC-DC converters, the input end of the rectifier is connected with an alternating current bus, and the output end of the rectifier is connected with a direct current bus through a fast fuse. In dc mode, the a and b active rectifiers and the c and d active rectifiers are powered by: the direct current voltage of the output end of each active rectifier is constant. The output ends of the e active rectifier and the f active rectifier are connected with the direct current bus through the fast fuses, and the input ends of the e active rectifier and the f active rectifier are respectively connected with the a shore power interface and the b shore power interface. When a ship is landed, shore power is rectified into direct current to be transmitted to a direct current bus, and the direct current is respectively charged to the storage battery pack a and the storage battery pack b through the bidirectional DC-DC unit a and the bidirectional DC-DC unit b.

The bidirectional DC-DC unit a, the bidirectional DC-DC unit b, the bidirectional DC-DC unit c, the bidirectional DC-DC unit d, the bidirectional DC-DC unit e and the bidirectional DC-DC unit f are all composed of direct current reactors and DC-DC converters, electric energy can flow in two directions, and the DC-DC converter ends of all the bidirectional DC-DC units are connected with a direct current bus through fast fuses. Wherein: and the direct current reactor ends of the a bidirectional DC-DC unit and the b bidirectional DC-DC unit are respectively connected with the a storage battery pack and the b storage battery pack. The direct current reactor ends of the c bidirectional DC-DC unit, the d bidirectional DC-DC unit, the e bidirectional DC-DC unit and the f bidirectional DC-DC unit are respectively connected with: a super capacitor group, b super capacitor group, c super capacitor group and d super capacitor group.

The battery pack a and the battery pack b consist of high-energy density units. The storage battery pack a and the storage battery pack b are respectively connected with the direct current bus through the bidirectional DC-DC unit a and the bidirectional DC-DC unit b, and the storage battery pack a and the storage battery pack b are respectively discharged to the direct current bus through the bidirectional DC-DC unit a and the bidirectional DC-DC unit b and can also be charged by receiving power from the direct current bus.

The daily power transformer and the daily power transformer are composed of an isolation transformer and two groups of switches at the input end of the isolation transformer. One group of switches is connected with an alternating current bus, the other group of switches is connected with an LC filter end of the fixed frequency inverter, and the output end of the isolation transformer is connected with a daily load. Wherein: a group of switches at the input ends of the daily power transformer and the daily power transformer are respectively connected with: the LC filter ends of the a fixed frequency inverter and the b fixed frequency inverter are connected, and the output ends of the A fixed frequency inverter and the b fixed frequency inverter are respectively connected with the a daily load and the b daily load. And in the alternating current mode, a switch connected with the alternating current bus is switched on, and a switch connected with the LC filter end is switched off. In the direct current mode, a switch connected with the LC filter end is switched on, and a switch connected with the alternating current bus is switched off.

The fixed-frequency inverter a and the fixed-frequency inverter b are composed of LC filters and DC-AC converters. Its input passes through fast acting fuse and is connected with direct current bus, its output respectively with: the input end switches of the a daily power supply transformer and the b daily power supply transformer are connected. In the direct current mode, direct current on a direct current bus is inverted into high-quality alternating current with fixed frequency, and the alternating current is supplied to a daily load through a daily power transformer.

The direct current bus includes: the bus A, the bus B, the bus C, the bus D, the fast fuses a, B and C, the switch A, the switch B and the switch C. In the alternating current mode, the switch A, the switch B and the switch C are switched off, and in the direct current mode, the switch A, the switch B and the switch C are switched on.

The input ends of the a frequency conversion inverter, the b frequency conversion inverter, the c frequency conversion inverter and the d frequency conversion inverter are connected with the direct current bus through the fast fuses, the output ends of the a frequency conversion inverter, the b frequency conversion inverter, the c frequency conversion inverter and the d frequency conversion inverter are respectively connected with the a main propulsion motor, the b side propulsion motor, the c side propulsion motor and the d main propulsion motor, the torque, the power and the rotating speed of the propulsion system can be controlled, and when the propulsion system does reverse work, electric energy can be fed to the direct current bus. The reverse work of the main propulsion motor a, the side propulsion motor b, the side propulsion motor c and the main propulsion motor d is fed to the direct current bus through the frequency conversion inverter a, the frequency conversion inverter b, the frequency conversion inverter c and the frequency conversion inverter d respectively. And charging and consuming the a super capacitor group, the b super capacitor group, the c super capacitor group and the d super capacitor group through the c bidirectional DC-DC unit, the d bidirectional DC-DC unit, the e bidirectional DC-DC unit and the f bidirectional DC-DC unit respectively.

The super capacitor group a, the super capacitor group b, the super capacitor group c and the super capacitor group d respectively pass through: and the c bidirectional DC-DC unit, the d bidirectional DC-DC unit, the e bidirectional DC-DC unit and the f bidirectional DC-DC unit are connected to the direct current bus. When the direct current bus loses power, the super capacitor group a, the super capacitor group b, the super capacitor group c and the super capacitor group d respectively pass through: and the c bidirectional DC-DC unit, the d bidirectional DC-DC unit, the e bidirectional DC-DC unit and the f bidirectional DC-DC unit are instantaneously discharged and injected with the electric energy of the direct current bus. When the direct current bus gains power, electric energy on the direct current bus respectively passes through the pairs of the c bidirectional DC-DC unit, the d bidirectional DC-DC unit, the e bidirectional DC-DC unit and the f bidirectional DC-DC unit: and the super capacitor group a, the super capacitor group b, the super capacitor group c and the super capacitor group d are instantly charged to consume the electric energy of the direct current bus. And power balance and fault ride-through are realized.

The method comprises the steps of switching on a switch a, a switch B and a switch C on an alternating current bus, switching off the switch A, the switch B and the switch C on the direct current bus, switching on switches connected with a daily power transformer a and a daily power transformer B and the alternating current bus, and switching off switches connected with LC filter ends of a fixed frequency inverter a and a fixed frequency inverter B, so that the alternating current networking mode can be entered. And each diesel generator set is synchronously merged into or disconnected from the AC bus through a switch controlled by the parallel controller. a active rectifier and b active rectifier and c active rectifier and d active rectifier and respectively: the frequency conversion inverter a, the frequency conversion inverter b, the frequency conversion inverter c and the frequency conversion inverter d are combined into a complete AC-DC-AC frequency converter which respectively controls and drives: a main propulsion motor, a side b propulsion motor, a side c propulsion motor and a main propulsion motor. Due to the action of the LC filters arranged in the active rectifier a and the active rectifier b, the active rectifier c and the active rectifier d, the harmonic distortion rate on the alternating current bus is lower than 5%. The load fluctuation of the main propulsion motor a, the side propulsion motor b, the side propulsion motor c and the main propulsion motor d respectively passes through: and the super capacitor group a connected with the bidirectional DC-DC unit, the super capacitor group b connected with the bidirectional DC-DC unit, the super capacitor group c connected with the bidirectional DC-DC unit and the super capacitor group d connected with the bidirectional DC-DC unit are used for balancing power. And the daily power supply transformer a and the daily power supply transformer b are powered by the alternating current bus by closing switches connected with the alternating current bus, so as to respectively provide power for the daily load a and the daily load b.

The method comprises the steps of opening a switch a and a switch B and a switch C on an alternating current bus, closing a switch A and a switch B and a switch C on the direct current bus, opening a switch connected with a daily power transformer a and a daily power transformer B and the alternating current bus, and closing a switch connected with LC filter ends of a fixed frequency inverter a and a fixed frequency inverter B, so that the direct current networking mode can be entered. The diesel generator set a, the diesel generator set b, the diesel generator set c and the diesel generator set d operate independently in speed regulation mode, and power is supplied to the direct-current bus through the active rectifier a, the active rectifier b, the active rectifier c and the active rectifier d. The storage battery pack a and the storage battery pack b are used for providing electric power for the direct current bus through the bidirectional DC-DC unit a and the bidirectional DC-DC unit b respectively to carry out independent propulsion, can also carry out combined propulsion with a diesel generator set, and can also receive power from the direct current bus through the bidirectional DC-DC unit a and the bidirectional DC-DC unit b respectively to charge the storage battery pack a and the storage battery pack b respectively. And switching on switches connected with LC filter ends of the a fixed frequency inverter and the b fixed frequency inverter to enable the a daily power transformer and the b daily power transformer to be respectively received by the direct current bus through the a fixed frequency inverter and the b fixed frequency inverter, so as to respectively provide low-harmonic high-quality power for the a daily load and the b daily load.

The system is provided with an alternating current bus and a direct current bus, and under the two extreme conditions, an alternating current networking mode and a direct current networking mode can cause the ship main propulsion system to lose power under the first condition that the active rectifier, the variable frequency inverter and the main diesel generator set fail and the second condition that the active rectifier, the variable frequency inverter and the main diesel generator set fail. In the first extreme case this can be achieved by: electric energy is solved by a diesel generating set → a bus → a switch → B bus → B switch → C bus → C switch → D bus → D active rectifier → D bus → C switch → C fast fuse → C bus → B switch → B fast fuse → B bus → A switch → a fast fuse → A bus → a frequency conversion inverter → an electric energy flow path reaching a main propulsion motor of a, so that the ship port propulsion motor obtains power. The second extreme may be by: electric energy is processed by a D diesel generating set → a bus bar → a switch → a bus bar → an active rectifier → a bus bar → a fast fuse → a switch → a bus bar → B fast fuse → B switch → C bus bar → C fast fuse → D bus bar → D inverter → electric energy flow path reaching a main propulsion motor, so that the starboard propeller of the ship obtains power. Therefore, the whole electric propulsion system has more redundancy and safety, the system is reliable and practical by using an alternating current mode during constant-speed cruising, and the system is energy-saving, low-emission and silent and economical by using a direct current mode during low speed or port entering.

The foregoing description is only an overview of the technical solutions of the present invention, and in order to make the technical means of the present invention more clearly understood, the present invention may be implemented according to the content of the description, and in order to make the above and other objects, features, and advantages of the present invention more obvious and understandable, the following preferred embodiments are described in detail with reference to the accompanying drawings.

Drawings

The utility model discloses totally 5 attached drawings, wherein.

Fig. 1 port and starboard standard configuration.

Fig. 2 is an ac networking mode.

Fig. 3 dc networking mode.

Fig. 4 shore charging mode.

Fig. 5 fault handling in the extreme case.

In the figure: 1a, a main diesel generator set, 1b, b diesel generator set, 1c, c diesel generator set, 1d, d diesel generator set, 1.1, synchronous diesel generator set, 1.2, switches controlled by a parallel controller, 2, alternating current bus, 2.1a, a bus, 2.1b, b bus, 2.1c, c bus, 2.1d, d bus, 2.2a, a switch, 2.2b, b switch, 2.2c, c switch, 3a, a active rectifier, 3b, b active rectifier, 3c, c active rectifier, 3d, d active rectifier, 3e, e active rectifier, 3f, f active rectifier, 3.1, LC filter, 3.2, AC-DC converter, 4a, a bidirectional DC-DC unit, 4b bidirectional DC-DC unit, 4c, c bidirectional DC-DC unit, 4d, d bidirectional DC-DC unit, 4e, e bidirectional DC-DC unit, 4f, f bidirectional DC-DC unit, 4.1, DC reactor, 4.2, DC-DC converter, 5a, a storage battery, 5B, B storage battery, 6a, a household power transformer, 6B, B household power transformer, 6.1, input switch 1, 6.2, input switch 2, 6.3, isolation transformer, 7a, a household load, 7B, B household load, 8a, a fixed frequency inverter, 8B, B fixed frequency inverter, 8.1, LC filter, 8.2, DC-AC converter, 9, DC bus, 9.1a, A bus, 9.1B, B bus, 9.1C, C bus, 9.1D, D bus, 9.2a, a fast fuse, 9.2B, B fast fuse, 9.2C, C fast fuse, 9.3a, A switch, 9.3B switch, B switch, 9.3C switch, C switch, 10a, a frequency conversion inverter, 10b, b frequency conversion inverter, 10c, c frequency conversion inverter, 10d, d frequency conversion inverter, 11a, a main propulsion motor, 11b, b side propulsion motor, 11c, c side propulsion motor, 11d, d main propulsion motor, 12a, a super capacitor group, 12b, b super capacitor group, 12c, c super capacitor group, 12d, d super capacitor group, 13a, a shore power interface, 13b, b shore power interface.

Detailed Description

A diesel-electric hybrid propulsion system for a ship with ac/dc networking as shown in fig. 1 to 5, comprising:

a diesel generator sets 1a and b diesel generator sets 1b, c diesel generator sets 1c and d diesel generator sets 1d, an alternating current bus 2, an a bus 2.1a, a b bus 2.1b, a c bus 2.1c and a d bus 2.1d, a switch 2.2a, a b switch 2.2b and a c switch 2.2c, an a active rectifier 3a, a b active rectifier 3b, a c active rectifier 3c, a d active rectifier 3d, an e active rectifier 3e and a f active rectifier 3f, an a bidirectional DC-DC unit 4a, a b bidirectional DC-DC unit 4b, a c bidirectional DC-DC unit 4c, a d bidirectional DC-DC unit 4d, an e bidirectional DC-DC unit 4e and a f bidirectional DC-DC unit 4f, a storage battery 5a and b storage battery 5b, an a household power transformer 6a and a household power transformer 6b, the system comprises a daily load 7a and a daily load 7B, a fixed frequency inverter 8a and a fixed frequency inverter 8B, a direct current bus 9, an A bus 9.1a, a B bus 9.1B, a C bus 9.1C, a D bus 9.1D, a fast fuse 9.2a, a fast fuse 9.2B, a C fast fuse 9.2C, an A switch 9.3a, a B switch 9.3B, a C switch 9.3C, a variable frequency inverter 10a, a variable frequency inverter 10B, a variable frequency inverter 10C, a variable frequency inverter 10D, a main propulsion motor 11a, a side propulsion motor 11B, a side propulsion motor 11C, a main propulsion motor 11D, an a super capacitor group 12a, a super capacitor group 12B, a super capacitor group 12C, a super capacitor group 12D, an a shore power interface 13a and a shore power interface 13C.

The system comprises a diesel generator set 1a, a diesel generator set 1b, a diesel generator set 1c and a diesel generator set 1d, wherein the diesel generator sets are composed of a synchronous generator set 1.1 and a switch 1.2, the synchronous generator sets are provided with a parallel controller, and the parallel controller is connected with an alternating current bus 2 through the switch 1.2 controlled by the parallel controller. Wherein: the system comprises a diesel generator set 1a, a diesel generator set 1b, a diesel generator set 1c, a diesel generator set 1d, a bus 2.1a, a bus 2.1b, a bus 2.1c, a bus 2.1d and a bus 2.1 d. In the ac mode, the generator sets are synchronously integrated into the ac bus 2 or disconnected from the ac bus 2 by the parallel controller and the switch 1.2. And in the direct current mode, each generator set operates at an independent speed regulation mode.

The alternating current bus 2 consists of a bus 2.1a, a bus 2.1b, a bus 2.1c, a bus 2.1d, a switch 2.2a, a switch 2.2b and a switch 2.2 c. In the ac mode, the switch 2.2a and the switch 2.2b of the switch a and the switch 2.2c of the switch c are switched on, and in the dc mode, the switch 2.2a and the switch 2.2b of the switch b and the switch 2.2c of the switch c are switched off.

The active rectifier 3a, the active rectifier 3b, the active rectifier 3c, the active rectifier 3d, the active rectifier 3e and the active rectifier 3f consist of an LC filter 3.1 and an AC-DC converter 3.2, the input end of the rectifier is connected with the AC bus 2, and the output end of the rectifier is connected with the DC bus 9 through a fast fuse. In a direct current mode, the diesel generator set 1a operates at independent speed regulation, the voltage and the frequency of the input end of the active rectifier 3a change along with the speed regulation, and the output end of the active rectifier 3a is connected with the direct current voltage which is transmitted to the A bus 9.1a through the fast fuse to be constant. B, the diesel generator set 1B operates at an independent speed regulation mode, the voltage and the frequency of the input end of the B active rectifier 3B change along with the speed regulation mode, and the output end of the B active rectifier 3B is connected with the direct-current voltage which is transmitted to the B bus 9.1B through the fast fuse to be constant. And C, the diesel generator set 1C operates at an independent speed regulation mode, the voltage and the frequency of the input end of the C active rectifier 3C change along with the speed regulation, and the output end of the C active rectifier 3C is connected with the constant direct-current voltage which is transmitted to the C bus 9.1C through the fast fuse. D the diesel generating set 1D operates with independent speed regulation, the voltage and the frequency of the input end of the D active rectifier 3D change with the speed regulation, and the output end of the D active rectifier 3D is connected with the direct current voltage which is transmitted to the D bus 9.1D through the fast fuse to be constant. The output end of an e active rectifier 3e is connected with an A bus 9.1a through a fast fuse, the input end of the e active rectifier is connected with an a shore power interface 13a, shore power is rectified to transmit electric energy to the A bus 9.1a when the ship is in shore, and the a bidirectional DC-DC unit 4a is used for charging the a storage battery pack 5 a. The output end of the f active rectifier 3f is connected with the D bus 9.1D through a fast fuse, the input end of the f active rectifier is connected with the b shore power interface 13b, when the ship is in shore, shore power is rectified to transmit electric energy to the D bus 9.1D, and the b bidirectional DC-DC unit 4b is used for charging the b storage battery pack 5 b.

The bidirectional DC-DC unit 4a, the bidirectional DC-DC unit 4b, the bidirectional DC-DC unit 4c, the bidirectional DC-DC unit 4d, the bidirectional DC-DC unit 4e and the bidirectional DC-DC unit 4f are composed of a direct current reactor 4.1 and a DC-DC converter 4.2, and electric energy can flow in two directions. The end 4.2 of the DC-DC converter of the bidirectional DC-DC unit 4a is connected with the A bus 9.1a through a fast fuse, and the end 4.1 of the direct current reactor is connected with the storage battery pack 5 a. And the end 4.2 of the DC-DC converter of the bi-directional DC-DC unit 4b is connected with the D bus 9.1D through a fast fuse, and the end 4.1 of the direct current reactor is connected with the storage battery pack 5 b. And the end 4.2 of the DC-DC converter of the c bidirectional DC-DC unit 4c is connected with the A bus 9.1a through a fast fuse, and the end 4.1 of the direct current reactor is connected with the a super capacitor bank 12 a. d, the end 4.2 of the DC-DC converter of the bidirectional DC-DC unit 4d is connected with the B bus 9.1B through a fast fuse, and the end 4.1 of the direct current reactor is connected with the B super capacitor bank 12B. The end 4.2 of the DC-DC converter of the e bidirectional DC-DC unit 4e is connected with the C bus 9.1C through a fast fuse, and the end 4.1 of the direct current reactor is connected with the C super capacitor bank 12C. The end 4.2 of the DC-DC converter of the f bidirectional DC-DC unit 4f is connected with the D bus 9.1D through a fast fuse, and the end 4.1 of the direct current reactor is connected with the D super capacitor bank 12D.

a secondary battery 5a and b secondary battery 5b, consisting of high energy density cells. The a storage battery pack 5a is connected to the A bus 9.1a through the a bidirectional DC-DC unit 4a, and the a storage battery pack 5a can discharge to the A bus 9.1a through the a bidirectional DC-DC unit 4a and can also receive power and charge from the A bus 9.1a through the a bidirectional DC-DC unit 4 a. The b storage battery pack 5b is connected to the D bus 9.1D through the b bidirectional DC-DC unit 4b, and the b storage battery pack 5b can discharge to the D bus (9.1D) through the b bidirectional DC-DC unit 4b and can also receive power and charge from the D bus 9.1D through the b bidirectional DC-DC unit 4 b.

a daily power transformer 6a and b daily power transformer 6b, which are composed of an isolation transformer 6.3, and a switch 6.1 and a switch 6.2 at the input end of the isolation transformer 6.3. The switch 6.2 of the a daily power transformer 6a is connected with the b bus 2.1b, the switch 6.1 is connected with the LC filter 8.1 end of the a fixed frequency inverter 8a, and the output end of the isolation transformer 6.3 is connected with the a daily load 7 a. A switch 6.2 of a b-day power transformer 6b is connected with a c bus 2.1c, a switch 6.1 is connected with an LC filter 8.1 end of a b-day frequency inverter 8b, and an output end of an isolation transformer 6.3 is connected with a b-day load 7 b. And in the alternating current mode, a switch connected with the alternating current bus 2 is switched on, and a switch connected with the 8.1 end of the LC filter is switched off. In the direct current mode, the switch connected with the end 8.1 of the LC filter is switched on, and the switch connected with the alternating current bus 2 is switched off.

and the a fixed-frequency inverter 8a and the b fixed-frequency inverter 8b consist of an LC filter 8.1 and a DC-AC converter 8.2. The input end of the a fixed frequency inverter 8a is connected with the B bus 9.1B through the fast fuse, and the output end is connected with the switch 6.1 of the a household power transformer 6 a. In the dc mode, the dc power on the B bus 9.1B is inverted into a high-quality ac power with a fixed frequency, and supplied to the consumer load 7 a. The input end of the b fixed frequency inverter 8b is connected with a C bus 9.1C through a fast fuse, and the output end of the b fixed frequency inverter is connected with a switch 6.1 of a b household power transformer 6 b. In the dc mode, the dc power on the C bus 9.1C is inverted into a high-quality ac power with a fixed frequency, and supplied to the household load 7 b.

The direct current bus 9 consists of an A bus 9.1a, a B bus 9.1B, a C bus 9.1C, a D bus 9.1D, an a fast fuse 9.2a, a B fast fuse 9.2B, a C fast fuse 9.2C, an A switch 9.3a, a B switch 9.3B and a C switch 9.3C. In the ac mode, the a switch 9.3a and the B switch 9.3B are switched off from the C switch 9.3C. In the dc mode, the a switch 9.3a and the B switch 9.3B are closed with the C switch (9.3C).

The input end of the a frequency conversion inverter 10a and the b frequency conversion inverter 10b, the c frequency conversion inverter 10c and the d frequency conversion inverter 10d are connected with the direct current bus 9 through the fast fuse, the output end of the a frequency conversion inverter is connected with the propulsion motor, the torque, the power and the rotating speed of the propulsion system can be controlled, and when the propulsion system does reverse work, electric energy can be fed to the direct current bus 9. Wherein: the a frequency conversion inverter 10a controls the a main propulsion motor 11a, when the a main propulsion motor 11a does reverse work, the a frequency conversion inverter 10a feeds electric energy to the A bus 9.1a, and the c bidirectional DC-DC unit 4c charges and absorbs the electric energy to the a super capacitor group 12 a. The B-side variable-frequency inverter 10B controls the B-side propulsion motor 11B, when the B-side propulsion motor 11B does reverse work, the B-side variable-frequency inverter 10B feeds electric energy to the B bus 9.1B, and the d-bidirectional DC-DC unit 4d charges and absorbs the electric energy to the B-side super capacitor group 12B. The C frequency conversion inverter 10C controls the C side propulsion motor 11C, when the C side propulsion motor 11C does reverse work, the C frequency conversion inverter 10C feeds electric energy to the C bus 9.1C, and the e bidirectional DC-DC unit 4e charges and absorbs the electric energy to the C super capacitor group 12C. The D frequency conversion inverter 10D controls the D main propulsion motor 11D, when the D main propulsion motor 11D does reverse work, the D frequency conversion inverter 10D feeds electric energy to the D bus 9.1D, and the f bidirectional DC-DC unit 4f charges and absorbs the electric energy to the D super capacitor group 12D.

a super capacitor group 12a and b super capacitor group 12b and c super capacitor group 12c and d super capacitor group 12d respectively pass through: the c bidirectional DC-DC unit 4c, the d bidirectional DC-DC unit 4d, the e bidirectional DC-DC unit 4e and the f bidirectional DC-DC unit 4f are connected to the direct current bus 9. When the A bus 9.1a is lack of work, the a super capacitor group 12a instantaneously discharges and injects electric energy into the A bus 9.1a through the c bidirectional DC-DC unit 4c, and when the A bus 9.1a gains work, the a super capacitor group 12a instantaneously consumes the electric energy of the A bus 9.1a through the c bidirectional DC-DC unit 4c to charge. When the B bus 9.1B is lack of power, the B super capacitor group 12B instantaneously discharges and injects electric energy into the B bus 9.1B through the d bidirectional DC-DC unit 4d, and when the B bus 9.1B gains power, the B super capacitor group 12B instantaneously consumes the electric energy of the B bus 9.1B through the d bidirectional DC-DC unit 4d for charging. When the C bus 9.1C is lack of power, the C super capacitor group 12C instantly discharges and injects electric energy of the C bus 9.1C through the e bidirectional DC-DC unit 4e, and when the C bus 9.1C is gained of power, the C super capacitor group 12C instantly consumes the electric energy of the C bus 9.1C through the e bidirectional DC-DC unit 4e for charging. When the D bus 9.1D is lack of work, the D super capacitor group 12D instantaneously discharges and injects the electric energy of the D bus 9.1D through the f bidirectional DC-DC unit 4f, and when the D bus 9.1D gains work, the D super capacitor group 12D instantaneously consumes the electric energy of the D bus 9.1D through the f bidirectional DC-DC unit 4f to charge. and a super capacitor group 12a and b and a super capacitor group 12b and c and a super capacitor group 12c and d realize power balance and fault ride-through.

The method comprises the steps of switching on a switch 2.2a and a switch 2.2B on an alternating current bus 2 and a switch 2.2C, switching off a switch 9.3a and a switch B9.3B on a direct current bus 9 and a switch C9.3C, switching on a switch connected with a daily power transformer 6a and a daily power transformer 6B on the alternating current bus 2, and switching off a switch connected with the end 8.1 of an LC filter, so that the alternating current networking mode can be entered. And each diesel generator set is synchronously merged into the alternating current bus 2 or disconnected from the alternating current bus 2 through the parallel controller and the switch 1.2. The a active rectifier 3a and the a frequency conversion inverter 10a are combined to form a complete AC-DC-AC frequency converter to control and drive the a main propulsion motor 11a, and the harmonic distortion rate on the AC bus 2 is lower than 5% due to the action of the a active rectifier 3a and the b active rectifier 3b and the LC filter 3.1 in the c active rectifier 3c and the d active rectifier 3 d. and (b) load fluctuation of the main propulsion motor 11a is carried out, and power balance is carried out through the super capacitor group (12a) connected with the bidirectional DC-DC unit (4 c). The b active rectifier 3b and the b frequency conversion inverter 10b are combined to form a complete AC-DC-AC frequency converter to control and drive the b side propulsion motor 11b, the load fluctuation of the b side propulsion motor 11b is controlled, and power balance is carried out through the b super capacitor group 12b connected with the d bidirectional DC-DC unit 4 d. The c active rectifier 3c and the c frequency conversion inverter 10c are combined to form a complete AC-DC-AC frequency converter to control and drive the c side propulsion motor 11c, the load fluctuation of the c side propulsion motor 11c is controlled, and power balance is carried out through the c super capacitor group 12c connected with the e bidirectional DC-DC unit 4 e. The d active rectifier 3d and the d frequency conversion inverter 10d are combined to form a complete AC-DC-AC frequency converter to control and drive the d main propulsion motor 11d, the load fluctuation of the d main propulsion motor 11d is controlled, and power balance is carried out through a d super capacitor group (12d) connected with the f bidirectional DC-DC unit (4 f). By closing the switch 6.2 of the a-day power transformer 6a, the a-day power transformer 6a is supplied with power from the ac bus 2 to the a-day load 7 a. The b-day power transformer 6b is powered by the ac bus 2 by closing the switch 6.2 of the b-day power transformer 6b, and supplies power to the b-day load 7 b.

The method comprises the steps of opening a switch 2.2a and a switch 2.2B on an alternating current bus 2 and a switch 2.2C on a C-switch, closing a switch 9.3a and a switch 9.3B on a direct current bus 9 and a switch 9.3C on a C-switch, opening a switch 6.2 on a daily power transformer 6a on a, closing a switch 6.1 on a daily power transformer 6B, opening a switch 6.2 on a daily power transformer 6B on a B, and closing the switch 6.1 on the same time, so that the direct current networking mode can be entered. and a diesel generator sets 1a and 1b and c and d are operated independently at different speeds. The method comprises the following steps that a the diesel generator set 1a supplies power to the direct current bus 9 through the active rectifier 3a, b the diesel generator set 1b supplies power to the direct current bus 9 through the active rectifier 3b, c the diesel generator set 1c supplies power to the direct current bus 9 through the active rectifier 3c, and d the diesel generator set 1d supplies power to the direct current bus 9 through the active rectifier 3 d. The a storage battery pack 5a supplies power to the direct current bus 9 through the a bidirectional DC-DC unit 4a for independent propulsion, can also be jointly propelled with a diesel generator set, and can also receive power from the direct current bus 9 through the a bidirectional DC-DC unit 4a to charge the a storage battery pack 5 a. The b storage battery pack 5b provides power for the direct current bus 9 through the b bidirectional DC-DC unit 4b for independent propulsion, can also be jointly propelled with a diesel generator set, and can also receive power from the direct current bus 9 through the b bidirectional DC-DC unit 4b to charge the b storage battery pack 5 b. The switch 6.1 of the switch-on a daily power transformer 6a is connected with the a fixed frequency inverter 8a, so that the a daily power transformer 6a receives the direct current bus 9 through the a fixed frequency inverter 8a and provides low harmonic high-quality power for the a daily load 7 a. And a switch 6.1 of a switch-on b daily power supply transformer 6b is connected with a b fixed frequency inverter 8b, so that the b daily power supply transformer 6b is received by a direct current bus 9 through the b fixed frequency inverter 8b, and low-harmonic high-quality power is supplied to a b daily load 7 b.

The system is provided with an alternating current bus 2 and a direct current bus 9, and under the two extreme conditions, an alternating current networking mode and a direct current networking mode can cause a ship main propulsion system to lose power under the first condition that an active rectifier 3a and a variable frequency inverter 10d and a diesel generator set 1d fail and the second condition that a active rectifier 3d and a variable frequency inverter 10a and a diesel generator set 1a fail. In the first extreme case this can be achieved by: the electric energy is solved by the power of the ship left thruster through a diesel generator set 1a → a bus bar 2.1a → a switch 2.2a → B bus bar 2.1B → B switch 2.2B → C bus bar 2.1C → C switch 2.2C → D bus bar 2.1D → D active rectifier 3D → D bus bar 9.1D → C switch 9.3C → C fast fuse 9.2C → C bus bar 9.1C → B switch 9.3B → B fast fuse 9.2B → B bus bar 9.3B → a switch 9.3a → a fast fuse 9.2a → a bus bar 9.1a → a inverter 10a → electric energy flow path of the a main thruster motor 11 a. The second extreme may be by: the electric energy is solved by the electric energy flow path of the D diesel generator set 1D → the D bus bar 2.1D → the C switch 2.2C → the C bus bar 2.1C → the B switch 2.2B → the B bus bar 2.1B → the a switch 2.2a → the a bus bar 2.1a → the a active rectifier 3a → the a bus bar 9.1a → the a fast fuse 9.2a → the a switch 9.3a → the B bus bar 9.1B → the B fast fuse 9.2B → the B switch 9.3B → the C bus bar 9.1C → the C fast fuse 9.2C → the C switch 9.3C → the D bus bar 9.1D → the D inverter 10D → the D main propulsion motor 11D, so that the right side propeller of the ship obtains power. The starboard propeller of the ship is powered. Therefore, the whole electric propulsion system has more redundancy and safety, the system is reliable and practical by using an alternating current mode during constant-speed cruising, and the system is energy-saving, low-emission and silent and economical by using a direct current mode during low speed or port entering.

The above description is only a preferred embodiment of the present invention, and the present invention is not limited to the above description in any form, and although the present invention has been disclosed with the preferred embodiment, it is not limited to the present invention, and any person skilled in the art can make some modifications or modifications to equivalent embodiments of the same changes without departing from the technical scope of the present invention, but all the technical matters of the present invention do not depart from the technical scope of the present invention.

Claims (4)

1. The utility model provides a diesel-electric hybrid electric propulsion system of boats and ships alternating current-direct current network deployment which characterized in that: comprises a diesel generator set (1a), a diesel generator set (1b), a diesel generator set (1c), a diesel generator set (1d), an alternating current bus (2), an active rectifier (3a), an active rectifier (3b), an active rectifier (3c), an active rectifier (3d), an active rectifier (3e), an active rectifier (3f), a bidirectional DC-DC unit (4a), a bidirectional DC-DC unit (4b), a bidirectional DC-DC unit (4c), a bidirectional DC-DC unit (4d), a bidirectional DC-DC unit (4e), a bidirectional DC-DC unit (4f), a storage battery pack (5a) and a storage battery pack (5b), a household power transformer (6a) and a household transformer (6b), a daily load (7a) and b daily load (7b), a fixed frequency inverter (8a) and b fixed frequency inverter (8b), a direct current bus (9), a frequency conversion inverter (10a) and b frequency conversion inverter (10b) and c frequency conversion inverter (10c) and d frequency conversion inverter (10d), a main propulsion motor (11a) and b side propulsion motor (11b) and c side propulsion motor (11c) and d main propulsion motor (11d), a super capacitor group (12a) and b super capacitor group (12b) and c super capacitor group (12c) and d super capacitor group (12d), a shore power interface (13a) and b shore power interface (13 b);

a diesel generating set (1a) and b diesel generating set (1b) and c diesel generating set (1c) and d diesel generating set (1d) include: the synchronous generator set (1.1) and the switch (1.2) are both provided with a parallel controller and are connected with the alternating current bus (2) through the switch (1.2) controlled by the parallel controller; wherein: a diesel generator set (1a) is connected with a bus (2.1a), b diesel generator set (1b) is connected with b bus (2.1b), c diesel generator set (1c) is connected with c bus (2.1c), d diesel generator set (1d) is connected with d bus (2.1 d);

the alternating current bus (2) comprises: a bus (2.1a), a bus (2.1b), a c bus (2.1c), a d bus (2.1d), a switch (2.2a), a switch (2.2b), and a c switch (2.2 c);

the active rectifier (3a), the active rectifier (3b), the active rectifier (3c), the active rectifier (3d), the active rectifier (3e) and the active rectifier (3f) are composed of LC filters (3.1) and AC-DC converters (3.2), the input end of the LC filters is connected with an alternating current bus (2), and the output end of the LC filters is connected with a direct current bus (9) through a fast fuse;

wherein: the input end of an active rectifier (3a) is connected with a bus (2.1a), and the output end of the active rectifier is connected with an A bus (9.1a) through a fast fuse;

the input end of the B active rectifier (3B) is connected with the B bus (2.1B), and the output end of the B active rectifier is connected with the B bus (9.1a) through the fast fuse;

the input end of the active rectifier (3a) is connected with the bus (2.1b) of C, and the output end of the active rectifier is connected with the bus (9.1C) of C through the fast fuse;

the input end of the D active rectifier (3D) is connected with the D bus (2.1D), and the output end of the D active rectifier is connected with the D bus (9.1D) through the fast fuse;

the output end of the e active rectifier (3e) is connected with an A bus (9.1a) through a fast fuse, and the input end of the e active rectifier is connected with an a shore power interface (13 a);

the output end of the f active rectifier (3f) is connected with a D bus (9.1D) through a fast fuse, and the input end of the f active rectifier is connected with a b shore power interface (13 b);

the a bidirectional DC-DC unit (4a), the b bidirectional DC-DC unit (4b), the c bidirectional DC-DC unit (4c), the d bidirectional DC-DC unit (4d), the e bidirectional DC-DC unit (4e) and the f bidirectional DC-DC unit (4f) are composed of a direct current reactor (4.1) and a DC-DC converter (4.2), and electric energy can flow in two directions;

wherein: the end of a DC-DC converter (4.2) of the bidirectional DC-DC unit (4a) is connected with an A bus (9.1a) through a fast fuse, and the end of a direct current reactor (4.1) is connected with a storage battery pack (5 a);

the end of a DC-DC converter (4.2) of the bidirectional DC-DC unit (4b) is connected with a D bus (9.1D) through a fast fuse, and the end of a direct current reactor (4.1) is connected with a storage battery pack (5b) of the bidirectional DC-DC unit (4 b);

the end of a DC-DC converter (4.2) of the c bidirectional DC-DC unit (4c) is connected with an A bus (9.1a) through a fast fuse, and the end of a direct current reactor (4.1) is connected with a super capacitor group (12 a);

d, the end of a DC-DC converter (4.2) of the bidirectional DC-DC unit (4d) is connected with a B bus (9.1B) through a fast fuse, and the end of a direct current reactor (4.1) is connected with a B super capacitor bank (12B);

the end of a DC-DC converter (4.2) of the e bidirectional DC-DC unit (4e) is connected with a C bus (9.1C) through a fast fuse, and the end of a direct current reactor (4.1) is connected with a C super capacitor bank (12C);

the end of a DC-DC converter (4.2) of the f bidirectional DC-DC unit (4f) is connected with a D bus (9.1D) through a fast fuse, and the end of a direct current reactor (4.1) is connected with a D super capacitor bank (12D);

the a storage battery pack (5a) and the b storage battery pack (5b) are composed of high-energy density units, can discharge to the direct current bus (9) through the bidirectional DC-DC unit, and can also receive power from the direct current bus (9) through the bidirectional DC-DC unit for charging;

wherein: the battery pack (5a) is connected with the end of a direct current reactor (4.1) of the bidirectional DC-DC unit (4a), and the battery pack (5b) is connected with the end of a direct current reactor (4.1) of the bidirectional DC-DC unit (4 b);

the daily power transformer (6a) and the daily power transformer (6b) are composed of an isolation transformer (6.3), a switch (6.1) and a switch (6.2) at the input end of the isolation transformer (6.3);

wherein: a switch (6.2) of a daily power transformer (6a) is connected with a bus (2.1b) of b, the switch (6.1) is connected with an LC filter (8.1) end of a fixed frequency inverter (8a), and the output end of an isolation transformer (6.3) is connected with a daily load (7 a);

a switch (6.2) of a daily power transformer (6b) is connected with a bus (2.1c) of the c, the switch (6.1) is connected with an LC filter (8.1) end of a fixed frequency inverter (8b) of the b, and an output end of an isolation transformer (6.3) is connected with a daily load (7b) of the b;

the a fixed frequency inverter (8a) and the b fixed frequency inverter (8b) are composed of an LC filter (8.1) and a DC-AC converter (8.2);

wherein: the input end of a fixed frequency inverter (8a) is connected with a B bus (9.1B) through a fast fuse, and the output end of the fixed frequency inverter is connected with a switch (6.1) of a household power transformer (6 a);

the input end of a b fixed frequency inverter (8b) is connected with a C bus (9.1C) through a fast fuse, and the output end of the b fixed frequency inverter is connected with a switch (6.1) of a b daily power transformer (6 b);

the direct current bus (9) comprises: the bus comprises a bus A (9.1a), a bus B (9.1B), a bus C (9.1C) and a bus D (9.1D), a fast fuse (9.2a), a fast fuse (9.2B) and a fast fuse C (9.2C), a switch A (9.3a), a switch B (9.3B) and a switch C (9.3C);

the input end of the a frequency conversion inverter (10a), the b frequency conversion inverter (10b), the c frequency conversion inverter (10c) and the d frequency conversion inverter (10d) is connected with the direct current bus (9) through a fast fuse, the output end of the a frequency conversion inverter is connected with the propulsion motor, the torque, the power and the rotating speed of the propulsion system can be controlled, and when the propulsion system does reverse work, electric energy can be fed to the direct current bus (9);

wherein: a frequency conversion inverter (10a) controls a main propulsion motor (11a), a b frequency conversion inverter (10b) controls a b side propulsion motor (11b), a c frequency conversion inverter (10c) controls a c side propulsion motor (11c), and a d frequency conversion inverter (10d) controls a d main propulsion motor (11 d);

the a super capacitor bank (12a) and the b super capacitor bank (12b) are connected with the c super capacitor bank (12c) and the d super capacitor bank (12d) and are connected with the end of a direct current reactor (4.1) of the bidirectional DC-DC unit;

when the direct current bus (9) loses power, the electric energy is injected into the direct current bus (9) through the instantaneous discharge of the bidirectional DC-DC unit;

when the direct current bus (9) gains power, the electric energy of the direct current bus (9) is instantly consumed by the bidirectional DC-DC unit for charging;

wherein: the super capacitor bank (12a) is connected with the end of a direct current reactor (4.1) of the c bidirectional DC-DC unit (4c), the super capacitor bank (12b) is connected with the end of a direct current reactor (4.1) of the d bidirectional DC-DC unit (4d), the super capacitor bank (12c) is connected with the end of a direct current reactor (4.1) of the e bidirectional DC-DC unit (4e), and the super capacitor bank (12d) is connected with the end of a direct current reactor (4.1) of the f bidirectional DC-DC unit (4f), so that power balance and fault ride-through are achieved.

2. The diesel-electric hybrid electric propulsion system for alternating current and direct current networking of ships according to claim 1, characterized in that: a switch (2.2a) and a switch (2.2B) on an alternating current bus (2) are switched on with a switch (2.2C), meanwhile, an A switch (9.3a) and a switch (9.3B) on a direct current bus (9) are switched off with a switch (9.3C), a daily power transformer (6a) and a daily power transformer (6B) on the direct current bus (9) are switched on with a switch (6.2) connected with the alternating current bus (2), and meanwhile, a switch (6.1) connected with the end of an LC filter (8.1) is switched off, so that the alternating current networking mode can be entered.

3. The diesel-electric hybrid propulsion system for ship alternating current and direct current networking is characterized in that a switch (2.2a) and a switch (2.2B) on an alternating current bus (2) are switched off from a switch (2.2C), a switch (9.3a) and a switch (9.3B) on a direct current bus (9) are switched off from a switch (9.3C), a switch (6.2) connecting a daily power transformer (6a) and a daily power transformer (6B) with the alternating current bus (2) is switched off, and a switch (6.1) connected with an LC filter (8.1) end is switched on, so that a direct current networking mode can be entered.

4. The diesel-electric hybrid electric propulsion system for alternating current-direct current networking of ships according to claim 1, which is configured with an alternating current bus (2) and a direct current bus (9), so that the whole electric propulsion system is more redundant and safer, an alternating current networking mode and a direct current networking mode can be switched with each other, the alternating current networking mode system is reliable and compact, and the direct current networking mode system is energy-saving, low in emission and economical in silence.

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