CN210768964U - Fluctuating electric power stabilizing device - Google Patents

Abstract

The utility model discloses an undulant electric power stabilising arrangement, the device is including electrolysis water unit, storage container, combustion chamber, turbine and condenser, the power of electrolysis water unit is established to undulant electric power, the oxyhydrogen mixture export of electrolysis water unit with the storage container intercommunication sets up oxyhydrogen mixture export with on the intercommunication passageway between the storage container and/or be in set up the working medium export on the storage container, the working medium export with the combustion chamber intercommunication sets up, the working medium export of combustion chamber with the working medium entry intercommunication of turbine sets up, the working medium export of turbine with the condenser is set up by cooling fluid passageway intercommunication, the condensation liquid export of condenser is through the force (forcing) pump, warp again after the heat absorption of electrolysis water unit with the combustion chamber intercommunication sets up. The utility model discloses a undulant electric power stabilising arrangement can overcome the poor defect of the availability of undulant electric power effectively, has very big using value and spreading value.

Description

Fluctuating electric power stabilizing device

Technical Field

The utility model relates to a heat energy and power field especially relate to a undulant electric power stabilising arrangement.

Background

Fluctuating power (such as wind power, photovoltaic power, tidal power, ocean current power, and the like) is an important component of new energy, but the fluctuation seriously hinders the availability of the fluctuating energy, and methods for stabilizing the fluctuating power such as a storage battery system and a compressed air system have been tried so far, but large-scale industrialization is difficult to realize. Therefore, a new type of surge power stabilizing device needs to be invented.

SUMMERY OF THE UTILITY MODEL

In order to solve the above problem, the utility model provides a technical scheme as follows:

scheme 1: the utility model provides an undulant electric power stabilising arrangement, the device is including electrolysis water unit, storage container, combustion chamber, turbine and condenser, the power of electrolysis water unit is established to undulant electric power, the oxyhydrogen mixture export of electrolysis water unit with the storage container intercommunication sets up oxyhydrogen mixture export with on the intercommunication passageway between the storage container and/or set up the working medium export on the storage container, the working medium export with the combustion chamber intercommunication sets up, the working medium export of combustion chamber with the working medium entry intercommunication of turbine sets up, the working medium export of turbine with the condenser is set up by cooling fluid passageway intercommunication, the condensation liquid export of condenser through the force (forcing) pump, pass through again after the electrolysis water unit heat absorption with the combustion chamber intercommunication sets up.

Scheme 2: a wave power stabilizing device comprises an electrolytic water unit, a storage container, a combustion chamber, a turbine and a condenser, the power supply of the electrolytic water unit is set as fluctuating power, the oxyhydrogen mixture outlet of the electrolytic water unit is communicated with the storage container, a working medium outlet is arranged on a communication channel between the oxyhydrogen mixture outlet and the storage container and/or on the storage container, the working medium outlet is communicated with the combustion chamber, the working medium outlet of the combustion chamber is communicated with the working medium inlet of the turbine, the working medium outlet of the turbine is communicated with the cooled fluid channel of the condenser, the condensed liquid outlet of the condenser is communicated with the combustion chamber after absorbing heat through the pressure pump and the electrolytic water unit, and the fluid in the cooled fluid channel of the condenser is seawater.

Scheme 3: a fluctuation electric power stabilizing device comprises an electrolytic water unit, a hydrogen storage container, an oxygen storage container, a combustion chamber, a turbine and a condenser, wherein a power supply of the electrolytic water unit is set as fluctuation electric power, a hydrogen outlet of the electrolytic water unit is communicated with the hydrogen storage container, an oxygen outlet of the electrolytic water unit is communicated with the oxygen storage container, a hydrogen guide outlet is arranged on a communication channel between the hydrogen outlet and the hydrogen storage container and/or on the hydrogen storage container, an oxygen guide outlet is arranged on a communication channel between the oxygen outlet and the oxygen storage container and/or on the oxygen storage container, the hydrogen guide outlet and the oxygen guide outlet are respectively communicated with the combustion chamber, a working medium outlet of the combustion chamber is communicated with a working medium inlet of the turbine, and a working medium outlet of the turbine is communicated with a cooled fluid channel of the condenser, and a condensed liquid outlet of the condenser is communicated with the combustion chamber after absorbing heat through the pressurizing pump and the electrolytic water unit.

Scheme 4: a fluctuation electric power stabilizing device comprises an electrolytic water unit, a hydrogen storage container, an oxygen storage container, a combustion chamber, a turbine and a condenser, wherein a power supply of the electrolytic water unit is set as fluctuation electric power, a hydrogen outlet of the electrolytic water unit is communicated with the hydrogen storage container, an oxygen outlet of the electrolytic water unit is communicated with the oxygen storage container, a hydrogen guide outlet is arranged on a communication channel between the hydrogen outlet and the hydrogen storage container and/or on the hydrogen storage container, an oxygen guide outlet is arranged on a communication channel between the oxygen outlet and the oxygen storage container and/or on the oxygen storage container, the hydrogen guide outlet and the oxygen guide outlet are respectively communicated with the combustion chamber, a working medium outlet of the combustion chamber is communicated with a working medium inlet of the turbine, and a working medium outlet of the turbine is communicated with a cooled fluid channel of the condenser, the condensed liquid outlet of the condenser is communicated with the combustion chamber after absorbing heat through the booster pump and the electrolytic water unit, and the fluid in the cooling fluid channel of the condenser is seawater.

Scheme 5: a wave power stabilization device includes a hydrocarbon synthesis unit, a storage vessel, a combustion chamber, a turbine, and a condenser, the power supply of the hydrocarbon synthesis unit is set as fluctuating power, the hydrocarbon and oxygen mixture outlet of the hydrocarbon synthesis unit is communicated with the storage container, a working medium outlet is arranged on the communication channel between the hydrocarbon and oxygen mixture outlet and the storage container and/or on the storage container, the working medium outlet is communicated with the combustion chamber, the working medium outlet of the combustion chamber is communicated with the working medium inlet of the turbine, the working medium outlet of the turbine is communicated with the cooled fluid channel of the condenser, and the condensed liquid outlet of the condenser is communicated with the combustion chamber after absorbing heat through the booster pump and the hydrocarbon synthesis unit.

Scheme 6: a fluctuation electric power stabilizing device comprises a hydrocarbon synthesis unit, a storage container, a combustion chamber, a turbine and a condenser, wherein a power supply of the hydrocarbon synthesis unit is set as fluctuation electric power, a hydrocarbon and oxygen mixture outlet of the hydrocarbon synthesis unit is communicated with the storage container, a working medium outlet is arranged on a communication channel between the hydrocarbon and oxygen mixture outlet and the storage container and/or on the storage container, the working medium outlet is communicated with the combustion chamber, a working medium outlet of the combustion chamber is communicated with a working medium inlet of the turbine, a working medium outlet of the turbine is communicated with a cooled fluid channel of the condenser, a condensed liquid outlet of the condenser is communicated with the combustion chamber after absorbing heat through the hydrocarbon synthesis unit by a pressure pump, the fluid in the cooling fluid channel of the condenser is set to be seawater.

Scheme 7: a wave power stabilizing device comprises a hydrocarbon synthesis unit, a hydrocarbon storage container, an oxygen storage container, a combustion chamber, a turbine and a condenser, wherein a power supply of the hydrocarbon synthesis unit is set to wave power, a hydrocarbon outlet of the hydrocarbon synthesis unit is communicated with the hydrocarbon storage container, an oxygen outlet of the hydrocarbon synthesis unit is communicated with the oxygen storage container, a hydrocarbon leading-out port is arranged on a communication channel between the hydrocarbon outlet and the hydrocarbon storage container and/or on the hydrocarbon storage container, an oxygen leading-out port is arranged on a communication channel between the oxygen outlet and the oxygen storage container and/or on the oxygen storage container, and the hydrocarbon leading-out port and the oxygen leading-out port are respectively communicated with the combustion chamber, the working medium outlet of the combustion chamber is communicated with the working medium inlet of the turbine, the working medium outlet of the turbine is communicated with the cooled fluid channel of the condenser, and the condensed liquid outlet of the condenser is communicated with the combustion chamber after absorbing heat through the pressurizing pump and the hydrocarbon synthesis unit.

Scheme 8: a wave power stabilizing device comprises a hydrocarbon synthesis unit, a hydrocarbon storage container, an oxygen storage container, a combustion chamber, a turbine and a condenser, wherein a power supply of the hydrocarbon synthesis unit is set to wave power, a hydrocarbon outlet of the hydrocarbon synthesis unit is communicated with the hydrocarbon storage container, an oxygen outlet of the hydrocarbon synthesis unit is communicated with the oxygen storage container, a hydrocarbon leading-out port is arranged on a communication channel between the hydrocarbon outlet and the hydrocarbon storage container and/or on the hydrocarbon storage container, an oxygen leading-out port is arranged on a communication channel between the oxygen outlet and the oxygen storage container and/or on the oxygen storage container, and the hydrocarbon leading-out port and the oxygen leading-out port are respectively communicated with the combustion chamber, the working medium outlet of the combustion chamber is communicated with the working medium inlet of the turbine, the working medium outlet of the turbine is communicated with the cooled fluid channel of the condenser, the condensed liquid outlet of the condenser is communicated with the combustion chamber after passing through the booster pump and absorbing heat through the hydrocarbon synthesis unit, and the fluid in the cooled fluid channel of the condenser is seawater.

In the present invention, the "hydrocarbon synthesis unit" refers to a chemical device that generates hydrocarbons and oxygen by using carbon dioxide, water, and electricity (with a catalyst being available).

In the present invention, necessary components, units or systems should be installed at necessary places according to the known technology in the field of heat energy and power.

The utility model has the advantages that the utility model discloses a undulant electric power stabilising arrangement can overcome the poor defect of the availability of undulant electric power effectively, has very big using value and spreading value.

Drawings

FIG. 1: the structure of embodiment 1 of the utility model is schematically shown;

FIG. 2: the structure of embodiment 2 of the utility model is schematically shown;

FIG. 3: the structure of embodiment 3 of the utility model is schematically shown;

FIG. 4: the structure of embodiment 4 of the utility model is schematically shown;

FIG. 5: the structure of embodiment 5 of the utility model is schematically shown;

FIG. 6: the utility model discloses embodiment 6's structural schematic diagram;

FIG. 7: the structure of embodiment 7 of the utility model is schematically shown;

FIG. 8: the structure of embodiment 8 of the utility model is schematically shown;

FIG. 9: the structure of embodiment 9 of the utility model is schematically shown;

FIG. 10: the structure of embodiment 10 of the present invention is schematically illustrated;

FIG. 11: the structure of embodiment 11 of the present invention is schematically illustrated;

FIG. 12: the structure of embodiment 12 of the present invention is schematically illustrated;

in the figure:

1 an electrolytic water unit; 2, storing the container; 3, a combustion chamber; 4, turbine; 5, a condenser; 6 a pressure pump; a 7-hydrocarbon synthesis unit; 8 a hydrocarbon storage vessel; 9 a control valve; 21 a hydrogen storage vessel; 22 an oxygen storage container; 51 the condenser is cooled by the fluid channel.

Detailed Description

Example 1

A wave power stabilizing apparatus, as shown in FIG. 1, includes an electrolytic water unit 1, a storage container 2, a combustion chamber 3, a turbine 4 and a condenser 5, the power supply of the electrolytic water unit 1 is set to be wave power, the oxyhydrogen mixture outlet of the electrolytic water unit 1 is communicated with the storage container 2, a working medium outlet is provided on the communication channel between the oxyhydrogen mixture outlet and the storage container 2 and on the storage container 2, the working medium outlet is communicated with the combustion chamber 3, the working medium outlet of the combustion chamber 3 is communicated with the working medium inlet of the turbine 4, the working medium outlet of the turbine 4 is communicated with the cooled fluid channel 51 of the condenser, and the condensed liquid outlet of the condenser 5 is communicated with the combustion chamber 3 after absorbing heat through the pressure pump 6 and the electrolytic water unit 1.

In the embodiment 1 of the present invention, it is further selectively chosen to make the electrolyzed water unit 1 provide the hydrogen-oxygen mixture directly to the combustion chamber 3 and/or make the storage container 2 store the hydrogen-oxygen mixture generated by the electrolyzed water unit 1 and provide the hydrogen-oxygen mixture to the combustion chamber 3.

Example 2

The utility model provides a undulant electric power stabilising arrangement, as shown in figure 2, the device includes electrolysis water unit 1, storage container 2, combustion chamber 3, turbine 4 and condenser 5, the power of electrolysis water unit 1 is established to undulant electric power, the oxyhydrogen mixture export of electrolysis water unit 1 with storage container 2 intercommunication sets up the working medium export on the storage container 2, the working medium export with combustion chamber 3 intercommunication sets up, the working medium export of combustion chamber 3 with the working medium entry intercommunication of turbine 4 sets up, the working medium export of turbine 4 with the condenser is by cooling fluid passage 51 intercommunication setting, the condensation liquid export of condenser 5 through force (forcing) pump 6, again through behind the heat absorption of electrolysis water unit 1 with combustion chamber 3 intercommunication sets up.

The embodiment 1 and the embodiment 2 of the present invention can set the control switch at the required position according to the actual requirement when the concrete implementation is performed. For example, a control valve 9 is provided at least one of the fluid inlet and the fluid outlet of the storage container 2 and/or a control valve 9 is provided on the passage between the working fluid outlet of the electrolyzed water unit 1 and the combustion chamber 3 and/or a control valve 9 is provided on the fluid passage between the condenser 5 and the combustion chamber 3; in practice, the control valve 9 may be selectively set or unset.

In practical implementation, the embodiment 2 and its changeable embodiments of the present invention can selectively make the electrolyzed water unit 1 provide the hydrogen-oxygen mixture to the combustion chamber 3 through the storage container 2; alternatively, the hydrogen-oxygen mixture generated by the electrolytic water unit 1 is stored in the storage vessel 2, and the storage vessel 2 may directly supply the hydrogen-oxygen mixture to the combustor 3 when necessary.

Example 3

The utility model provides a undulant electric power stabilising arrangement, as shown in fig. 3, the device includes electrolysis water unit 1, storage container 2, combustion chamber 3, turbine 4 and condenser 5, the power of electrolysis water unit 1 is established to undulant electric power, the oxyhydrogen mixture export of electrolysis water unit 1 with storage container 2 intercommunication sets up oxyhydrogen mixture export with set up the working medium export on the intercommunication passageway between the storage container 2, the working medium export with combustion chamber 3 intercommunication sets up, the working medium export of combustion chamber 3 with the working medium entry intercommunication of turbine 4 sets up, the working medium export of turbine 4 with the condenser is by cooling fluid passage 51 intercommunication setting, the condensation liquid export of condenser 5 through force (forcing) pump 6, again through after the heat absorption of electrolysis water unit 1 with combustion chamber 3 intercommunication sets up.

The embodiment 3 of the utility model provides a when concrete implementation, can set up control switch according to actual need in the position of needs. For example, a control valve 9 is provided at the fluid inlet of the storage vessel 2 and/or a control valve 9 is provided on the passage between the oxyhydrogen mixture outlet of the electrolyzed water unit 1 and the combustion chamber 3 and/or a control valve 9 is provided on the fluid passage between the condenser 5 and the combustion chamber 3; in practice, the control valve 9 may be selectively set or unset.

In practical implementation of embodiment 3 and its alternative embodiment, the electrolyzed water unit 1 can be selectively used to directly supply the hydrogen-oxygen mixture to the combustion chamber 3; or, the hydrogen-oxygen mixture generated by the electrolytic water unit 1 is stored in the storage container 2, and when it is actually needed, the storage container 2 can directly supply the hydrogen-oxygen mixture to the combustion chamber 3; or, the electrolytic water unit 1 and the storage container 2 are simultaneously supplied with the hydrogen-oxygen mixture to the combustion chamber 3.

Example 4

A fluctuation electric power stabilizing apparatus, as shown in FIG. 4, the apparatus includes an electrolyzed water unit 1, a hydrogen storage container 21, an oxygen storage container 22, a combustion chamber 3, a turbine 4 and a condenser 5, the power supply of the electrolyzed water unit 1 is set as fluctuation electric power, a hydrogen outlet of the electrolyzed water unit 1 is communicated with the hydrogen storage container 21, an oxygen outlet of the electrolyzed water unit 1 is communicated with the oxygen storage container 22, a hydrogen leading outlet is arranged on a communication passage between the hydrogen outlet and the hydrogen storage container 21 and on the hydrogen storage container 21, an oxygen leading outlet is arranged on a communication passage between the oxygen outlet and the oxygen storage container 22 and on the oxygen storage container 22, the hydrogen leading outlet and the oxygen leading outlet are respectively communicated with the combustion chamber 3, a working medium outlet of the combustion chamber 3 is communicated with a working medium inlet of the turbine 4, the working medium outlet of the turbine 4 is communicated with the cooled fluid channel 51 of the condenser, and the condensed liquid outlet of the condenser 5 is communicated with the combustion chamber 3 after absorbing heat through the pressure pump 6 and the electrolytic water unit 1.

In practical implementation of embodiment 4 and its convertible embodiment, the electrolyzed water unit 1 may be further selectively supplied with hydrogen gas directly to the combustion chamber 3 and/or the hydrogen storage container 21 may be further selectively supplied with hydrogen gas to the combustion chamber 3.

In practical implementation of embodiment 4 and its convertible embodiment, the electrolyzed water unit 1 may be further selectively provided to directly supply oxygen to the combustion chamber 3 and/or the oxygen storage container 22 may be provided to supply oxygen to the combustion chamber 3.

Example 5

A fluctuation electric power stabilizing device is shown in figure 5 and comprises an electrolyzed water unit 1, a hydrogen storage container 21, an oxygen storage container 22, a combustion chamber 3, a turbine 4 and a condenser 5, wherein the power supply of the electrolyzed water unit 1 is set as fluctuation electric power, a hydrogen outlet of the electrolyzed water unit 1 is communicated with the hydrogen storage container 21, an oxygen outlet of the electrolyzed water unit 1 is communicated with the oxygen storage container 22, a hydrogen outlet is arranged on the hydrogen storage container 21, an oxygen outlet is arranged on the oxygen storage container 22, the hydrogen outlet and the oxygen outlet are respectively communicated with the combustion chamber 3, a working medium outlet of the combustion chamber 3 is communicated with a working medium inlet of the turbine 4, a working medium outlet of the turbine 4 is communicated with a cooled fluid passage 51 of the condenser, and a condensed liquid outlet of the condenser 5 is communicated with a cooled fluid passage 51 of the condenser through a pressurizing pump 6, And then is communicated with the combustion chamber 3 after absorbing heat by the electrolytic water unit 1.

As an alternative embodiment, in example 5 of the present invention, a hydrogen gas leading-out port may be further selectively provided in the communication passage between the hydrogen gas outlet and the hydrogen storage container 21, and the hydrogen gas leading-out port may be provided to communicate with the combustion chamber 3.

Alternatively, in example 5 of the present invention, an oxygen outlet may be further selectively provided in the communication passage between the oxygen outlet and the oxygen storage container 22, and the oxygen outlet may be communicated with the combustion chamber 3.

As an alternative embodiment, the embodiments 4 and 5 and their alternative embodiments of the present invention can be implemented by providing a control switch at a desired position according to actual needs. For example, a control valve 9 is provided at least one of the fluid inlet and the fluid outlet of the hydrogen storage container 21 and/or a control valve 9 is provided on the fluid path between the hydrogen gas outlet and the combustion chamber 3 and/or a control valve 9 is provided on the fluid inlet and the fluid outlet of the oxygen storage container 22 and/or a control valve 9 is provided on the fluid path between the oxygen gas outlet and the combustion chamber 3 and/or a control valve 9 is provided on the fluid path between the condenser 5 and the combustion chamber 3; in practice, the control valve 9 may be selectively set or unset.

In practical implementation of embodiment 5 and its convertible embodiment, the electrolyzed water unit 1 can be selectively supplied with hydrogen gas to the combustion chamber 3 through the hydrogen storage container 21; alternatively, the hydrogen gas generated by the electrolytic water unit 1 is stored in the hydrogen storage container 21, and the hydrogen storage container 21 may directly supply the hydrogen gas to the combustor 3 when necessary.

In practical implementation of embodiment 5 and its alternative embodiments, the electrolyzed water unit 1 can be selectively supplied with oxygen to the combustion chamber 3 through the oxygen storage container 22; alternatively, the oxygen gas generated by the electrolytic water unit 1 is stored in the oxygen storage container 22, and the oxygen storage container 22 may directly supply the oxygen gas to the combustion chamber 3 when necessary.

Example 6

A fluctuation electric power stabilizing device is shown in figure 6, the device comprises an electrolytic water unit 1, a hydrogen storage container 21, an oxygen storage container 22, a combustion chamber 3, a turbine 4 and a condenser 5, the power supply of the electrolytic water unit 1 is set as fluctuation electric power, a hydrogen outlet of the electrolytic water unit 1 is communicated with the hydrogen storage container 21, an oxygen outlet of the electrolytic water unit 1 is communicated with the oxygen storage container 22, a hydrogen guide outlet is arranged on a communication channel between the hydrogen outlet and the hydrogen storage container 21, an oxygen guide outlet is arranged on a communication channel between the oxygen outlet and the oxygen storage container 22, the hydrogen guide outlet and the oxygen guide outlet are respectively communicated with the combustion chamber 3, a working medium outlet of the combustion chamber 3 is communicated with a working medium inlet of the turbine 4, a working medium outlet of the turbine 4 is communicated with a cooled fluid channel 51 of the condenser, and a condensed liquid outlet of the condenser 5 is communicated with the combustion chamber 3 after absorbing heat through the booster pump 6 and the electrolytic water unit 1.

As a changeable implementation manner, in the embodiment 6 of the present invention, a control switch may be provided at a desired position according to actual needs. For example, a control valve 9 is provided at the fluid inlet of the hydrogen storage container 21 and/or a control valve 9 is provided on the fluid passage between the hydrogen outlet of the electrolyzed water unit 1 and the combustion chamber 3 and/or a control valve 9 is provided at the fluid inlet of the oxygen storage container 22 and/or a control valve 9 is provided on the fluid passage between the oxygen outlet of the electrolyzed water unit 1 and the combustion chamber 3 and/or a control valve 9 is provided on the fluid passage between the condenser 5 and the combustion chamber 3; in practice, the control valve 9 may be selectively set or unset.

In practical implementation of embodiment 6 and its alternative embodiment, the electrolyzed water unit 1 can be selectively used to directly supply hydrogen to the combustion chamber 3; or, the hydrogen generated by the electrolytic water unit 1 is stored in the hydrogen storage container 21, and the hydrogen storage container 21 can directly supply hydrogen to the combustion chamber 3 when actually needed; or the electrolyzed water unit 1 and the hydrogen storage container 21 are caused to supply hydrogen gas to the combustor 3 at the same time.

In practical implementation of embodiment 6 and its alternative embodiment, the electrolyzed water unit 1 can be selectively used to directly supply oxygen to the combustion chamber 3; or, the oxygen generated by the electrolytic water unit 1 is stored in the oxygen storage container 22, and the oxygen storage container 22 can directly provide oxygen to the combustion chamber 3 when actually needed; or, the electrolyzed water unit 1 and the oxygen storage container 22 are simultaneously supplied with oxygen to the combustion chamber 3.

Example 7

A fluctuation electric power stabilizing device is shown in figure 7 and comprises a hydrocarbon synthesis unit 7, a storage container 2, a combustion chamber 3, a turbine 4 and a condenser 5, wherein the power supply of the hydrocarbon synthesis unit 7 is set as fluctuation electric power, a hydrocarbon and oxygen mixture outlet of the hydrocarbon synthesis unit 7 is communicated with the storage container 2, a working medium outlet is arranged on a communication channel between the hydrocarbon and oxygen mixture outlet and the storage container 2 and on the storage container 2, the working medium outlet is communicated with the combustion chamber 3, a working medium outlet of the combustion chamber 3 is communicated with a working medium inlet of the turbine 4, a working medium outlet of the turbine 4 is communicated with a cooled fluid channel 51 of the condenser, and a condensed liquid outlet of the condenser 5 is connected with a cooling fluid channel 51 of the condenser through a pressurizing pump 6, And then is communicated with the combustion chamber 3 after absorbing heat by the hydrocarbon synthesis unit 7.

In the embodiment 7 of the present invention, when the hydrocarbon synthesis unit 7 is implemented, it is further selectively selected to enable the combustion chamber 3 to directly provide the mixture of hydrocarbons and oxygen and/or the storage container 2 to provide the mixture of hydrocarbons and oxygen to the combustion chamber 3.

Example 8

A fluctuation electric power stabilizing device is shown in figure 8 and comprises a hydrocarbon synthesis unit 7, a storage container 2, a combustion chamber 3, a turbine 4 and a condenser 5, wherein a power supply of the hydrocarbon synthesis unit 7 is set as fluctuation electric power, a hydrocarbon and oxygen mixture outlet of the hydrocarbon synthesis unit 7 is communicated with the storage container 2, a working medium outlet is formed in the storage container 2 and communicated with the combustion chamber 3, a working medium outlet of the combustion chamber 3 is communicated with a working medium inlet of the turbine 4, a working medium outlet of the turbine 4 is communicated with a cooled fluid passage 51 of the condenser, and a condensed liquid outlet of the condenser 5 is communicated with the combustion chamber 3 after absorbing heat through a pressurizing pump 6 and the hydrocarbon synthesis unit 7.

The embodiment 7 and the embodiment 8 of the present invention can set the control switch at the required position according to the actual requirement when the concrete implementation is performed. For example, a control valve 9 is provided at least one of the fluid inlet and the fluid outlet of the storage container 2 and/or a control valve 9 is provided on the fluid path between the hydrocarbon and oxygen mixture outlet and the combustion chamber 3 and/or a control valve 9 is provided on the fluid path between the condenser 5 and the combustion chamber 3; in practice, the control valve 9 may be selectively set or unset.

In practical implementation of embodiment 8 and its convertible embodiment, the hydrocarbon synthesis unit 7 can be selectively used to provide a mixture of hydrocarbons and oxygen to the combustion chamber 3 through the storage container 2; alternatively, the hydrocarbon and oxygen mixture generated by the hydrocarbon synthesis unit 7 is stored in the storage container 2, and the storage container 2 can directly supply the hydrocarbon and oxygen mixture to the combustion chamber 3 when necessary.

Example 9

A wave power stabilizing apparatus, as shown in FIG. 9, includes a hydrocarbon synthesis unit 7, a storage vessel 2, a combustion chamber 3, a turbine 4 and a condenser 5, the power supply of the hydrocarbon synthesis unit 7 is set to wave power, the hydrocarbon and oxygen mixture outlet of the hydrocarbon synthesis unit 7 is communicated with the storage container 2, a working medium outlet is arranged on a communication channel between the hydrocarbon and oxygen mixture outlet and the storage container 2, the working medium outlet is communicated with the combustion chamber 3, the working medium outlet of the combustion chamber 3 is communicated with the working medium inlet of the turbine 4, the working medium outlet of the turbine 4 is communicated with the cooled fluid channel 51 of the condenser, and the condensed liquid outlet of the condenser 5 is communicated with the combustion chamber 3 after absorbing heat through the booster pump 6 and the hydrocarbon synthesis unit 7.

The embodiment 9 of the utility model provides a when concrete implementation, can set up control switch according to actual need in the position of needs. For example, a control valve 9 is provided at the fluid inlet of the storage vessel 2 and/or a control valve 9 is provided on the fluid path between the hydrocarbon synthesis unit 7 and the combustion chamber 3 and/or a control valve 9 is provided on the fluid path between the condenser 5 and the combustion chamber 3; in practice, the control valve 9 may be selectively set or unset.

In practical implementation, the embodiment 9 and its changeable implementation mode of the present invention can selectively make the hydrocarbon synthesis unit 7 directly provide the mixture of hydrocarbon and oxygen to the combustion chamber 3; or, the hydrogen-oxygen mixture generated by the hydrocarbon synthesis unit 7 is stored in the storage container 2, and the storage container 2 can directly provide the hydrocarbon and oxygen mixture to the combustion chamber 3 when actually needed; or, the hydrocarbon synthesis unit 7 and the storage container 2 are used for simultaneously providing the mixture of hydrocarbon and oxygen to the combustion chamber 3.

Example 10

A wave power stabilizing apparatus, as shown in FIG. 10, comprising a hydrocarbon synthesis unit 7, a hydrocarbon storage container 8, an oxygen storage container 22, a combustion chamber 3, a turbine 4 and a condenser 5, a power supply of the hydrocarbon synthesis unit 7 being set to wave power, a hydrocarbon outlet of the hydrocarbon synthesis unit 7 being provided in communication with the hydrocarbon storage container 8, an oxygen outlet of the hydrocarbon synthesis unit 7 being provided in communication with the oxygen storage container 22, a hydrocarbon delivery port being provided on a communication passage between the hydrocarbon outlet and the hydrocarbon storage container 8 and on the hydrocarbon storage container 8, an oxygen delivery port being provided on a communication passage between the oxygen outlet and the oxygen storage container 22 and on the oxygen storage container 22, the hydrocarbon guide outlet and the oxygen guide outlet are respectively communicated with the combustion chamber 3, a working medium outlet of the combustion chamber 3 is communicated with a working medium inlet of the turbine 4, a working medium outlet of the turbine 4 is communicated with the cooled fluid passage 51 of the condenser, and a condensed liquid outlet of the condenser 5 is communicated with the combustion chamber 3 after absorbing heat through the pressurizing pump 6 and the hydrocarbon synthesis unit 7.

In practical implementation of the embodiment 10 and its convertible embodiment, the hydrocarbon synthesis unit 7 can be further selectively provided to directly provide the hydrocarbon to the combustion chamber 3 and/or the hydrocarbon storage container 8 can be provided to provide the hydrocarbon to the combustion chamber 3.

In particular, example 10 and its alternative embodiments of the present invention may further optionally be implemented such that the hydrocarbon synthesis unit 7 provides oxygen directly to the combustion chamber 3 and/or the oxygen storage container 22 provides oxygen to the combustion chamber 3.

Example 11

A wave power stabilizing device, as shown in FIG. 11, the device comprises a hydrocarbon synthesis unit 7, a hydrocarbon storage container 8, an oxygen storage container 22, a combustion chamber 3, a turbine 4 and a condenser 5, the power supply of the hydrocarbon synthesis unit 7 is set as wave power, the hydrocarbon outlet of the hydrocarbon synthesis unit 7 is communicated with the hydrocarbon storage container 8, the oxygen outlet of the hydrocarbon synthesis unit 7 is communicated with the oxygen storage container 22, the hydrocarbon outlet of the hydrocarbon storage container 8 is provided with a hydrocarbon outlet, the oxygen storage container 22 is provided with an oxygen outlet, the hydrocarbon outlet and the oxygen outlet are respectively communicated with the combustion chamber 3, the working medium outlet of the combustion chamber 3 is communicated with the working medium inlet of the turbine 4, the working medium outlet of the turbine 4 is communicated with the cooled fluid channel 51 of the condenser, and the condensed liquid outlet of the condenser 5 is communicated with the combustion chamber 3 after absorbing heat through the booster pump 6 and the hydrocarbon synthesis unit 7.

Alternatively, in example 11 of the present invention, a hydrocarbon outlet port may be further selectively provided in the communication passage between the hydrocarbon outlet port and the hydrocarbon reservoir 8, and the hydrocarbon outlet port may be provided in communication with the combustion chamber 3.

Alternatively, in example 11 of the present invention, an oxygen outlet may be further selectively provided in the communication passage between the oxygen outlet and the oxygen storage container 22, and the oxygen outlet may be communicated with the combustion chamber 3.

As an alternative embodiment, the embodiment 10 and the embodiment 11 and their alternative embodiments of the present invention can be implemented by providing a control switch at a desired position according to actual needs. For example, a control valve 9 is provided at least one of a fluid inlet and a fluid outlet of the hydrocarbon storage vessel 8 and/or a control valve 9 is provided at least one of a fluid inlet and a fluid outlet of the oxygen storage vessel 22 and/or a control valve 9 is provided on a fluid passage between the hydrocarbon synthesis unit 7 and the combustion chamber 3 and/or a control valve 9 is provided on a fluid passage between the condenser 5 and the combustion chamber 3; in practice, the control valve 9 may be selectively set or unset.

In practical implementation, the embodiment 11 and its convertible embodiment of the present invention can selectively make the hydrocarbon synthesis unit 7 supply hydrocarbon to the combustion chamber 3 through the hydrocarbon storage container 8; alternatively, the hydrocarbons produced by the hydrocarbon synthesis unit 7 are stored in the hydrocarbon storage container 8, and the hydrocarbon storage container 8 may directly supply the hydrocarbons to the combustion chamber 3 when necessary.

In particular embodiments of example 11 and its alternative embodiments, the hydrocarbon synthesis unit 7 may be selectively supplied with oxygen to the combustion chamber 3 via the oxygen storage vessel 22; alternatively, the oxygen generated by the hydrocarbon synthesis unit 7 is stored in the oxygen storage container 22, and the oxygen storage container 22 may directly supply oxygen to the combustion chamber 3 when necessary.

Example 12

A wave power stabilizing apparatus, as shown in FIG. 12, comprising a hydrocarbon synthesis unit 7, a hydrocarbon storage container 8, an oxygen storage container 22, a combustion chamber 3, a turbine 4 and a condenser 5, a power supply of the hydrocarbon synthesis unit 7 being set to wave power, a hydrocarbon outlet of the hydrocarbon synthesis unit 7 being provided in communication with the hydrocarbon storage container 8, an oxygen outlet of the hydrocarbon synthesis unit 7 being provided in communication with the oxygen storage container 22, a hydrocarbon delivery port being provided on a communication passage between the hydrocarbon outlet and the hydrocarbon storage container 8, an oxygen delivery port being provided on a communication passage between the oxygen outlet and the oxygen storage container 22, the hydrocarbon delivery port and the oxygen delivery port being provided in communication with the combustion chamber 3, respectively, the working medium outlet of the combustion chamber 3 is communicated with the working medium inlet of the turbine 4, the working medium outlet of the turbine 4 is communicated with the cooled fluid channel 51 of the condenser, and the condensed liquid outlet of the condenser 5 is communicated with the combustion chamber 3 after absorbing heat through the pressurizing pump 6 and the hydrocarbon synthesis unit 7.

As an alternative implementation manner, in the embodiment 12 of the present invention, a control switch may be provided at a desired position according to actual needs when the implementation is performed. For example, a control valve 9 is provided at the fluid inlet of the hydrocarbon storage vessel 8 and/or a control valve 9 is provided at the fluid inlet of the oxygen storage vessel 22 and/or a control valve 9 is provided on the fluid passage between the hydrocarbon synthesis unit 7 and the combustion chamber 3 and/or a control valve 9 is provided on the fluid passage between the condenser 5 and the combustion chamber 3; in practice, the control valve 9 may be selectively set or unset.

As an alternative embodiment, the control valve 9 used in the embodiments of the present invention is a generic term for all valves capable of performing a control function, and includes different types of control valves.

In practical implementation, the embodiment 12 and its convertible embodiment can selectively make the hydrocarbon synthesis unit 7 directly supply hydrocarbon to the combustion chamber 3; or, the hydrocarbon produced by the hydrocarbon synthesis unit 7 is stored in the hydrocarbon storage container 8, and when the need actually arises, the hydrocarbon storage container 8 can directly supply the hydrocarbon to the combustion chamber 3; or the hydrocarbon synthesis unit 7 and the hydrocarbon storage container 8 are caused to supply the hydrocarbon to the combustion chamber 3 simultaneously.

In particular embodiments of example 12 and its alternative embodiments, the hydrocarbon synthesis unit 7 may be selectively configured to provide oxygen directly to the combustion chamber 3; or, the oxygen generated by the hydrocarbon synthesis unit 7 is stored in the oxygen storage container 22, and the oxygen storage container 22 can directly provide oxygen to the combustion chamber 3 when actually needed; alternatively, the hydrocarbon synthesis unit 7 and the oxygen storage container 22 are caused to supply oxygen to the combustion chamber 3 simultaneously.

In the present invention, as an alternative embodiment, the fluid in the cooling fluid passage of the condenser 5 may be selected to be seawater in practice.

In all the embodiments of the invention, the compound is generated by mainly utilizing fluctuating power, and is stored, so that the compound is combusted in the combustion chamber to generate a high-temperature and high-pressure working medium to drive the turbine; and condensing the exhausted steam discharged by the turbine or condensing the exhausted steam discharged by the turbine by using seawater, and introducing the condensed steam into the combustion chamber after absorbing the waste heat generated in the process of generating the compound by the fluctuating power. Wherein the compound can be selectively set as water or hydrocarbon, etc.

The utility model discloses aforementioned all embodiments selectively make when concrete implementation wave power establishes to wind-powered electricity generation, photoelectricity or water and electricity etc..

The drawings of the utility model are only schematic, and any technical scheme that satisfies this application writing and record all belongs to the scope of protection of this application.

Obviously, the present invention is not limited to the above embodiments, and many modifications can be derived or suggested according to the known technology in the field and the technical solutions disclosed in the present invention, and all of these modifications should also be considered as the protection scope of the present invention.

Claims (8)

1. A fluctuating power stabilizing device characterized by: the device comprises an electrolytic water unit (1), a storage container (2), a combustion chamber (3), a turbine (4) and a condenser (5), the power supply of the electrolytic water unit (1) is set as fluctuating power, the oxyhydrogen mixture outlet of the electrolytic water unit (1) is communicated with the storage container (2), a working medium outlet is arranged on a communication channel between the oxyhydrogen mixture outlet and the storage container (2) and/or on the storage container (2), the working medium outlet is communicated with the combustion chamber (3), the working medium outlet of the combustion chamber (3) is communicated with the working medium inlet of the turbine (4), the working medium outlet of the turbine (4) is communicated with the cooled fluid channel (51) of the condenser, and a condensed liquid outlet of the condenser (5) is communicated with the combustion chamber (3) after absorbing heat through the water electrolysis unit (1) via the booster pump (6).

2. A fluctuating power stabilizing device characterized by: the device comprises an electrolytic water unit (1), a storage container (2), a combustion chamber (3), a turbine (4) and a condenser (5), wherein the power supply of the electrolytic water unit (1) is set to be fluctuating power, an oxyhydrogen mixture outlet of the electrolytic water unit (1) is communicated with the storage container (2), the oxyhydrogen mixture outlet is communicated with a communication channel between the storage container (2) and/or a working medium outlet is arranged on the storage container (2), the working medium outlet is communicated with the combustion chamber (3), the working medium outlet of the combustion chamber (3) is communicated with a working medium inlet of the turbine (4), the working medium outlet of the turbine (4) is communicated with the condenser through a cooling fluid channel (51), a condensed liquid outlet of the condenser (5) is communicated with the combustion chamber (3) through a pressure pump (6) and then the electrolytic water unit (1) absorbs heat, the fluid in the cooling fluid channel of the condenser (5) is set to be seawater.

3. A fluctuating power stabilizing device characterized by: the device comprises an electrolytic water unit (1), a hydrogen storage container (21), an oxygen storage container (22), a combustion chamber (3), a turbine (4) and a condenser (5), wherein a power supply of the electrolytic water unit (1) is set to be fluctuating power, a hydrogen outlet of the electrolytic water unit (1) is communicated with the hydrogen storage container (21), an oxygen outlet of the electrolytic water unit (1) is communicated with the oxygen storage container (22), a hydrogen guide outlet is arranged on a communication channel between the hydrogen outlet and the hydrogen storage container (21) and/or on the hydrogen storage container (21), an oxygen guide outlet is arranged on a communication channel between the oxygen outlet and the oxygen storage container (22) and/or on the oxygen storage container (22), and the hydrogen guide outlet and the oxygen guide outlet are respectively communicated with the combustion chamber (3), the working medium outlet of the combustion chamber (3) is communicated with the working medium inlet of the turbine (4), the working medium outlet of the turbine (4) is communicated with the cooled fluid channel (51) of the condenser, and the condensed liquid outlet of the condenser (5) is communicated with the combustion chamber (3) after absorbing heat through the electrolyzed water unit (1) and the booster pump (6).

4. A fluctuating power stabilizing device characterized by: the device comprises an electrolytic water unit (1), a hydrogen storage container (21), an oxygen storage container (22), a combustion chamber (3), a turbine (4) and a condenser (5), wherein a power supply of the electrolytic water unit (1) is set to be fluctuating power, a hydrogen outlet of the electrolytic water unit (1) is communicated with the hydrogen storage container (21), an oxygen outlet of the electrolytic water unit (1) is communicated with the oxygen storage container (22), a hydrogen guide outlet is arranged on a communication channel between the hydrogen outlet and the hydrogen storage container (21) and/or on the hydrogen storage container (21), an oxygen guide outlet is arranged on a communication channel between the oxygen outlet and the oxygen storage container (22) and/or on the oxygen storage container (22), and the hydrogen guide outlet and the oxygen guide outlet are respectively communicated with the combustion chamber (3), the working medium outlet of the combustion chamber (3) is communicated with the working medium inlet of the turbine (4), the working medium outlet of the turbine (4) is communicated with the condenser through a cooling fluid channel (51), a condensed liquid outlet of the condenser (5) is communicated with the combustion chamber (3) after being subjected to heat absorption by the electrolyzed water unit (1) through a pressure pump (6), and fluid in the cooling fluid channel of the condenser (5) is set as seawater.

5. A fluctuating power stabilizing device characterized by: the device comprises a hydrocarbon synthesis unit (7), a storage container (2), a combustion chamber (3), a turbine (4) and a condenser (5), wherein a power supply of the hydrocarbon synthesis unit (7) is set to be fluctuating power, a hydrocarbon and oxygen mixture outlet of the hydrocarbon synthesis unit (7) is communicated with the storage container (2), a working medium outlet is formed in a communication channel between the hydrocarbon and oxygen mixture outlet and the storage container (2) and/or in the storage container (2), the working medium outlet is communicated with the combustion chamber (3), a working medium outlet of the combustion chamber (3) is communicated with a working medium inlet of the turbine (4), a working medium outlet of the turbine (4) is communicated with a cooled fluid channel (51) of the condenser, and a condensed liquid outlet of the condenser (5) is communicated with a pressure pump (6), And then the heat is absorbed by the hydrocarbon synthesis unit (7) and then the combustion chamber (3) is communicated.

6. A fluctuating power stabilizing device characterized by: the device comprises a hydrocarbon synthesis unit (7), a storage container (2), a combustion chamber (3), a turbine (4) and a condenser (5), wherein a power supply of the hydrocarbon synthesis unit (7) is set to be fluctuating power, a hydrocarbon and oxygen mixture outlet of the hydrocarbon synthesis unit (7) is communicated with the storage container (2), a working medium outlet is formed in a communication channel between the hydrocarbon and oxygen mixture outlet and the storage container (2) and/or in the storage container (2), the working medium outlet is communicated with the combustion chamber (3), a working medium outlet of the combustion chamber (3) is communicated with a working medium inlet of the turbine (4), a working medium outlet of the turbine (4) is communicated with a cooled fluid channel (51) of the condenser, and a condensed liquid outlet of the condenser (5) is communicated with a pressure pump (6), And then the heat is absorbed by the hydrocarbon synthesis unit (7) and then is communicated with the combustion chamber (3), and the fluid in the cooling fluid channel of the condenser (5) is seawater.

7. A fluctuating power stabilizing device characterized by: the device comprises a hydrocarbon synthesis unit (7), a hydrocarbon storage container (8), an oxygen storage container (22), a combustion chamber (3), a turbine (4) and a condenser (5), wherein a power supply of the hydrocarbon synthesis unit (7) is set to be fluctuating power, a hydrocarbon outlet of the hydrocarbon synthesis unit (7) is communicated with the hydrocarbon storage container (8), an oxygen outlet of the hydrocarbon synthesis unit (7) is communicated with the oxygen storage container (22), a hydrocarbon guide outlet is arranged on a communication channel between the hydrocarbon outlet and the hydrocarbon storage container (8) and/or on the hydrocarbon storage container (8), an oxygen guide outlet is arranged on a communication channel between the oxygen outlet and the oxygen storage container (22) and/or on the oxygen storage container (22), the hydrocarbon guide outlet and the oxygen guide outlet are respectively communicated with the combustion chamber (3), a working medium outlet of the combustion chamber (3) is communicated with a working medium inlet of the turbine (4), a working medium outlet of the turbine (4) is communicated with the cooled fluid channel (51) of the condenser, and a condensed liquid outlet of the condenser (5) is communicated with the combustion chamber (3) after being subjected to heat absorption by the hydrocarbon synthesis unit (7) through the pressure pump (6).

8. A fluctuating power stabilizing device characterized by: the device comprises a hydrocarbon synthesis unit (7), a hydrocarbon storage container (8), an oxygen storage container (22), a combustion chamber (3), a turbine (4) and a condenser (5), wherein a power supply of the hydrocarbon synthesis unit (7) is set to be fluctuating power, a hydrocarbon outlet of the hydrocarbon synthesis unit (7) is communicated with the hydrocarbon storage container (8), an oxygen outlet of the hydrocarbon synthesis unit (7) is communicated with the oxygen storage container (22), a hydrocarbon guide outlet is arranged on a communication channel between the hydrocarbon outlet and the hydrocarbon storage container (8) and/or on the hydrocarbon storage container (8), an oxygen guide outlet is arranged on a communication channel between the oxygen outlet and the oxygen storage container (22) and/or on the oxygen storage container (22), the hydrocarbon outlet and the oxygen outlet are communicated with the combustion chamber (3) respectively, a working medium outlet of the combustion chamber (3) is communicated with a working medium inlet of the turbine (4), a working medium outlet of the turbine (4) is communicated with the condenser through a cooled fluid channel (51), a condensed liquid outlet of the condenser (5) is communicated with the combustion chamber (3) after being subjected to heat absorption by the hydrocarbon synthesis unit (7) through a pressure pump (6), and fluid in the cooled fluid channel of the condenser (5) is set as seawater.

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