KR102106869B1 - Rankine cycle power generation and its operation method - Google Patents

Abstract

The power generation system according to the present invention includes a heater for transferring heat to a working fluid, a turbine for converting the thermal energy of the working fluid passing through the heater into mechanical energy, a first condenser receiving heat from the working fluid passing through the turbine, A first pump for moving the working fluid passing through the first condenser to the heater, a circulation circuit providing a path for the working fluid to circulate through the first pump, the heater, the turbine and the first condenser, the A gas that is branched from a circulation circuit between a heater and the turbine, and a first branch circuit through which at least a portion of the working fluid passing through the heater can move, a gas connected to the turbine, and an accommodation space formed in communication with the first branch circuit A bearing is provided, and the rotating shaft is supported by a working fluid passing through the receiving space and communicating with the receiving space. And it may include a recovery circuit which is formed so as to join the circulation circuit is provided with a working fluid having passed through the receiving space of the first condenser, the front end or rear end.

Description

Rankine cycle power generation system and its operation method

The present invention relates to a power generation system of the Rankine cycle and a method for operating the same, and more particularly, to a power generation system including a generator connected to a turbine constituting the Rankine cycle and the Rankine cycle and a method of operating the same.

In a power generation system including a Rankine cycle and a generator connected to a turbine constituting the Rankine cycle, the working medium in a high temperature and high pressure state is passed through a turbine to convert thermal energy into mechanical energy, and the generator has its axis connected to the turbine. Various technologies have been introduced to convert mechanical energy into electrical energy.

At this time, in relation to the driving of the generator, the bearing may be a configuration that is essentially required to stably support and rotate the shaft of the generator.

In particular, in the bearings required as described above, as ball bearings need to be periodically replaced with consumables, there is a problem that not only takes cost and time, but also affects the overall efficiency of the power generation system.

The present invention may be an invention related to a system and an operating method for use as a gas bearing of a generator using a working fluid to solve the above problem.

The present invention is to provide a power generation system including a generator connected to a turbine constituting the Rankine cycle and the Rankine cycle as an invention devised to solve the problems of the prior art described above.

Further, it is to provide a method of operating a power generation system including a generator connected to a turbine constituting the Rankine cycle and the Rankine cycle.

The problems of the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

The power generation system of the present invention for achieving the above object is a heater for transferring heat to the working fluid, a turbine for converting the thermal energy of the working fluid passing through the heater to mechanical energy, heat from the working fluid passing through the turbine A first condenser to be delivered, a first pump to move the working fluid passing through the first condenser to the heater, a path for the working fluid to circulate through the first pump, the heater, the turbine and the first condenser A circulating circuit provided, a first branch circuit that is branched from a circulation circuit between the heater and the turbine and through which the at least a portion of the working fluid passes may be moved, connected to the turbine, and in communication with the first branch circuit A gas bearing in which an accommodation space is formed is provided, and a generator whose rotation axis is supported by a working fluid passing through the accommodation space and It may include a recovery circuit which is formed so as to communicate with the group receiving space and, joined to the circuit which is provided a working fluid passing through the accommodation space of the first condenser, the front end or rear end.

That is, a heater for transferring heat to the working fluid, a turbine for converting the thermal energy of the working fluid passing through the heater into mechanical energy, a first condenser receiving heat from the working fluid passing through the turbine, and the first condenser A Rankine cycle provided with a first pump for moving the working fluid passing through the heater and a circulation circuit for providing a path for the working fluid to circulate through the first pump, the heater, the turbine, and the first condenser. A power generation system comprising a generator connected to a turbine to convert mechanical energy into electrical energy, the power generation system comprising: a first capable of moving at least a portion of a working fluid branched from a circulation circuit between the heater and the turbine and passed through the heater; A branch circuit, an accommodation space provided in communication with the first branch circuit at a location adjacent to the generator, is provided. The gas bearing supporting the rotating shaft of the generator through the working fluid passing through the receiving space and the working space communicating with the receiving space, and passing the working fluid through the receiving space into a circulation circuit provided at the front or rear end of the first condenser It may include a recovery circuit formed to.

At this time, further comprising a bypass circuit branched from the circulation circuit between the heater and the turbine, the bypass circuit is formed so that at least a portion of the working fluid passing through the heater moves and joins the first branch circuit The working fluid passing through the heater may be moved to the bypass circuit before the working fluid passing through the turbine.

In addition, the circulation circuit may include a circulation circuit valve that controls at least one of a flow direction and a flow rate of the working fluid passing through the heater.

Alternatively, the first branch circuit may be characterized in that the working fluid moving the first branch circuit is formed to receive heat from the heater.

The heating unit may further include a heating unit capable of controlling the dryness of the working fluid flowing into the receiving space by heating the working fluid flowing into the receiving space.

At this time, the heating unit may be characterized in that it is installed in the first branch circuit.

In addition, the circulation circuit may include a first storage unit provided between the first condenser and the first pump to control the flow rate of the working fluid moving to the first pump.

Alternatively, the generator may further include a ball bearing installed in the accommodation space and supporting the rotation shaft of the generator together with the gas bearing.

And a second branch circuit branched from the recovery circuit, the second branch circuit being formed such that at least a portion of the working fluid passing through the accommodation space moves and joins the circulation circuit between the first condenser and the first pump. When the pressure of the working fluid passing through the receiving space is lower than the pressure of the working fluid passing through the turbine, at least a part of the working fluid passing through the receiving space may be moved to the second branch circuit. have.

At this time, the recovery circuit may include a recovery circuit valve that controls at least one of the flow direction and flow rate of the working fluid passing through the accommodation space.

In this case, the recovery circuit may include a recovery circuit sensor that measures at least one of temperature and pressure of the working fluid passing through the accommodation space.

Alternatively, the second branch circuit may include a second pump that increases the pressure of the working fluid flowing into the second branch circuit.

Alternatively, the second branch circuit may include a second condenser receiving heat from the working fluid moving to the second pump, and a second storage unit controlling the flow rate of the working fluid passing through the second condenser.

And it is formed on the outside of the turbine, it may further include a separator for partitioning the turbine and the generator.

A method of operating the power generation system of the present invention for achieving the above object is a heater for transferring heat to a working fluid, a turbine for converting the thermal energy of the working fluid passing through the heater to mechanical energy, a working fluid passing through the turbine A first condenser receiving heat from the first pump, a first pump to move the working fluid passing through the first condenser to the heater, and the working fluid to circulate the first pump, the heater, the turbine, and the first condenser In a power generation system including a Rankine cycle provided with a circulation circuit providing a path for the generator and a generator connected to the turbine to convert mechanical energy into electrical energy, before the working fluid passing through the heater moves to the turbine , Is provided adjacent to the generator via a first branch circuit branched between the heater and the turbine. After the gas bearing operation step, the working fluid passing through the heater moves to a bypass circuit formed between the heater and the turbine and joined to the first branch circuit so as to move to the accommodation space. , A turbine operation step in which the working fluid passing through the heater moves to at least one of the first branch circuit and the turbine, and a working fluid moving from the first branch circuit passes through the accommodation space to the rear end of the turbine and the condenser. It may include a recovery step of moving to a recovery circuit joined to the circulation circuit provided between and a condenser flow step of at least one of the working fluid passing through the turbine and the working fluid passing through the receiving space flows to the condenser. have.

At this time, the gas bearing operation step includes a heating unit operation step heated by a heating unit installed in the first branch circuit when the dryness of the working fluid moving through the first branch circuit is smaller than a preset value. can do.

Or in the recovery step, when the pressure of the working fluid passing through the receiving space is lower than the pressure of the working fluid passing through the turbine, at least a part of the working fluid passing through the receiving space is branched from the recovery circuit and the first It may include a step through a second branch circuit to move to the first pump via a second branch circuit formed to be joined to the circulation circuit provided between the first condenser and the first pump.

In addition, the step of passing through the second branch circuit may include a second pump operation step via a second pump installed in the second branch circuit to increase the pressure of the working fluid flowing into the second branch circuit.

Alternatively, the turbine operation step is a flow rate control step of increasing the amount of working fluid moving to the first branch circuit when the pressure of the working fluid passing through the receiving space is lower than the pressure of the working fluid before passing through the condenser. It may include.

Method for operating the power generation system of the present invention for achieving the above object A heater for transferring heat to a working fluid, a turbine for converting the thermal energy of the working fluid passing through the heater to mechanical energy, from the working fluid passing through the turbine A first condenser that receives heat, a first pump for moving the working fluid passing through the first condenser to the heater, and a working fluid for circulating the first pump, the heater, the turbine, and the first condenser A power generation system comprising a Rankine cycle provided with a circulation circuit providing a path and a generator connected to the turbine to convert mechanical energy into electrical energy, wherein the working fluid passing through the heater is the front end of the heater and the turbine A first branch circuit moving step moving to a first branch circuit branching between, and moving from the first branch circuit Gas activating step of moving to a recovery circuit joined to a circulation circuit provided between the turbine and the condenser via a receiving space provided with a working fluid adjacent to the generator, a part of the working fluid passing through the heater It may include a step of activating the turbine to move to the turbine, and at least one of the working fluid passing through the turbine and the working fluid passing through the receiving space to flow to the condenser.

The power generation system of the present invention and an operation method thereof for solving the above problems have the following effects.

First, the working fluid of the Rankine cycle can be used as a bearing of the generator, thereby significantly reducing the cost and burden for replacement and maintenance of the bearing.

Second, theoretically, it is possible to use the bearing semi-permanently, so it is expected to increase the overall efficiency of the power generation system.

Third, it is possible to control the dryness of the working fluid used in the gas bearing, thereby preventing damage to the generator.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will become apparent to those skilled in the art from the description of the claims.

1 is a view of a first embodiment of the power generation system of the present invention.
2 is a view of a second embodiment of the power generation system of the present invention.
3 is a view showing a heating unit added to the first embodiment of the power generation system of the present invention.
4 is a view showing a heating unit added to the second embodiment of the power generation system of the present invention.
5 is a view of a third embodiment of the heating unit of the power generation system of the present invention.
6 is a view showing a ball bearing coupled to the gas bearing of the power generation system of the present invention.
And Figures 7 and 8 is a view showing the operation method of the power generation system of the present invention.

Hereinafter, preferred embodiments of the present invention, in which the object of the present invention can be specifically realized, will be described with reference to the accompanying drawings. In describing the present embodiment, the same name and the same code are used for the same configuration, and additional description will be omitted.

In addition, in describing the embodiments of the present invention, it is revealed in advance that components having the same function use the same name and the same reference numerals and are not substantially identical to the conventional ones.

In addition, the terms used in the embodiments of the present invention are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

In addition, in the embodiments of the present invention, terms such as "include" or "have" are intended to indicate that there are features, numbers, steps, operations, components, parts, or a combination thereof described in the specification, but one Or further features or numbers, steps, operations, components, parts, or combinations thereof, should not be excluded in advance.

The power generation system of the present invention will be described with reference to FIGS. 1 to 6.

According to FIGS. 1 to 6, the power generation system of the present invention may include a Rankine cycle, a first branch circuit 400, a generator 800, and a recovery circuit 600.

The Rankine cycle includes a heater 20 that transfers heat to the working fluid, a turbine 30 for converting the thermal energy of the working fluid that has passed through the heater 20 into mechanical energy, and the working fluid that has passed through the turbine 30. A first condenser 40 that receives heat from the first pump 10 that moves the working fluid passing through the first condenser 40 to the heater 20 and the working fluid is the first pump 10 ), The heater 20, the turbine 30 and the first condenser 40 may be provided with a circulation circuit 200 that provides a path for circulating.

The first branch circuit 400 may be formed to move at least a portion of the working fluid that is branched from the circulation circuit 220 between the heater 20 and the turbine 30 and passes through the heater 20.

That is, the working fluid that has passed through the heater 20 may move to the circulation circuit 220 and the initial circuit 280 between the heater 20 and the turbine 30.

Specifically, in the operation of the first power generation system, a part of the working fluid that has passed through the heater 20 flows into the first branch circuit 400 to serve as a gas bearing of the generator 800 to be described later. And the rest of the working fluid that has passed through the heater 20 flows to the initial circuit 280 to form a cycle.

At this time, when the rest of the working fluid does not flow to the initial circuit 280 and flows into the turbine 30, a problem may arise that the shaft of the generator 800 connected to the turbine 30 is not supported. In the case of the present invention, in order to solve the above problems, the initial circuit 280 may provide a path through which the rest of the working fluid passing through the heater 20 except for the working fluid flowing to the first branch circuit 400 flows. .

The generator 800 may be configured such that a rotor connected to the turbine 30 and the shaft system rotates adjacent to the stator, and an induced current is generated to convert mechanical energy into electrical energy. Alternatively, the generator 800 may be integrally formed with the turbine 30.

Specifically, the generator 800 may be provided with a gas bearing in which an accommodation space is formed in communication with the first branch circuit adjacent to the axis of the generator 800. In addition, the rotating shaft of the generator is supported by the working fluid passing through the accommodation space and can perform the function of gas bearing.

That is, the gas bearing may be provided with an accommodation space 820 in communication with the first branch circuit 400 at a position adjacent to the generator 800. At this time, the gas bearing may be a configuration of a general gas bearing, and in the case of the present invention, the working fluid passing through the accommodation space 820 through the first branch circuit 400 supports the rotational shaft 810 of the generator. Bearings can be configured.

In the present invention, since the working fluid passing through the heater 20 may constitute a part of the gas bearing, the wear of the bearing does not occur compared to the ball bearing, and thus, an increase in overall power generation efficiency can be expected.

The recovery circuit 600 may be formed to join the working fluid that has passed through the receiving space 820 to the circulation circuit 200 provided at the front end or the rear end of the first condenser 40.

That is, the recovery circuit 600 may provide a path through which the working fluid passing through the receiving space 820 joins the circulation circuit 200. The working circuit via the first branch circuit 400 and the accommodation space 820 is again joined to the circulation circuit 200 by the recovery circuit 600 to form a cycle of the closed circuit as a whole.

According to FIG. 1, the circulation circuit 200 may include a circulation circuit valve 290 that controls at least one of the flow direction and flow rate of the working fluid passing through the heater 20.

The circulation circuit valve 290 may control the flow of the working fluid such that the working fluid passing through the heater 20 moves to the first branch circuit 400 and to the initial circuit 280 during initial operation. At this time, the working fluid moved to the first branch circuit 400 may pass through the accommodation space 820 provided in the gas bearing and support the rotating shaft 810 of the generator.

Thereafter, the circulation circuit valve 290 may move the working fluid passing through the heater 20 to maintain the gas bearing to the first branch circuit 400. In addition, the remaining working fluid other than the working fluid moving to the first branch circuit 400 may be moved to the turbine 30 to operate the turbine 30.

The circulation circuit valve 290 may be a three-way valve, but is not limited thereto, and may be variously applied as long as it is a configuration capable of implementing the above functions.

In the case of the second embodiment, the rest of the first embodiment and the above-described contents may be formed in the same configuration.

According to FIG. 2, the power generation system of the present invention is a bypass circuit 500 that is branched from the circulation circuit 220 between the heater 20 and the turbine 30 and is formed to join the first branch circuit 400. It may further include.

The bypass circuit 500 receives the working fluid passing through the heater 20 via the first branch circuit 400 before the working fluid passing through the heater 20 moves to the turbine 30. A path may be provided to the working fluid passing through the heater 20 so as to be moved to the space 820.

Specifically, the generator 800 of the present invention constitutes a gas bearing that supports the shaft 810 of the generator through a working fluid circulating through the Rankine cycle. In this case, there is a risk of damage to the generator 800 when the working fluid flows into the turbine 30 before the working fluid flows into the gas bearing. Therefore, the present invention can solve the above risks because the working fluid that has passed through the heater 20 moves to the bypass circuit 500 and moves into the receiving space 820 of the gas bearing before moving to the turbine 30.

However, it is not necessarily limited to the above configuration in order to implement the effects of the present invention.

And the power generation system of the present invention, as can be seen in Figures 3 and 4, heating the working fluid flowing into the receiving space 820 to control the dryness of the working fluid flowing into the receiving space 820 The unit 300 may be further included.

Specifically, the heating unit 300, it is preferable to maintain the dryness of the working fluid flowing into the receiving space 820 to 1.

This is because when the dryness of the working fluid flowing into the receiving space 820 is lower than 1, the working fluid contains a liquid, and the liquid may cause a problem in the generator 800.

In addition, the heating unit 300 is preferably installed in the first branch circuit 400. However, this is for the efficiency of heat transfer to the working fluid of the heating unit 300, but is not limited thereto and may be variously formed.

For example, referring to FIG. 5, the first branch circuit 400 may be formed so that a working fluid moving the first branch circuit 400 can receive heat from the heater 20.

In addition, the circulation circuit 200 is provided between the first condenser 40 and the first pump 10, a first storage unit for controlling the flow rate of the working fluid moving to the first pump 10 ( 50).

When the level sensor is provided in the first storage unit 50 and the working fluid passing through the first condenser 40 by the level sensor forms a constant amount, the working fluid is moved to the first pump 10. I can do it.

Further, in the power generation system of the present invention, a ball bearing 830 is installed in the accommodation space 820 to support the rotation shaft 810 of the generator together with the gas bearing.

As shown in FIG. 6, the ball bearing 830 may be provided coupled to the shaft, and may perform a function of a bearing when there is a problem such as that a working fluid does not flow into the receiving space 820.

In addition, the power generation system of the present invention, the second branch circuit is formed to be branched from the recovery circuit 600 and joined to the circulation circuit 240 provided between the first condenser 40 and the first pump 10 It may further include (700).

And when the pressure of the working fluid passing through the receiving space 820 is lower than the pressure of the working fluid passing through the turbine 30, at least a part of the working fluid passing through the receiving space 820 is the second branch It may be characterized by moving to the first pump 10 via the circuit 700.

At this time, the recovery circuit 600 may include a recovery circuit valve 610 that controls at least one of the flow direction and flow rate of the working fluid passing through the receiving space 820.

In addition, the recovery circuit 600 may include a recovery circuit sensor 620 that measures at least one of temperature and pressure of the working fluid passing through the accommodation space 820.

The recovery circuit valve 610 and the recovery circuit sensor 620 may interlock to control the working fluid.

Specifically, an operation signal may be transmitted to the recovery circuit valve 610 by comparing the pressure of the working fluid measured by the recovery circuit sensor 620 with the pressure of the working fluid passing through the turbine 30. In addition, the recovery circuit valve 610 may move the working fluid passing through the accommodation space 820 to at least one of the recovery circuit 600 and the second branch circuit 700 according to the operation signal. .

In addition, the second branch circuit 700 heats from the working fluid moving to the second pump 710 and the second pump 710 to increase the pressure of the working fluid flowing into the second branch circuit 700. It may include a second condenser 740 to receive the second storage unit 750 for controlling the flow rate of the working fluid passing through the second condenser 740.

The working fluid flowing into the second branch circuit 700 may be changed into a liquid phase through the second condenser 740. In addition, the working fluid changed to a liquid phase may be stored in the second storage unit 750. At this time, the second storage unit 750 may be provided with a level sensor. When the working fluid stored in the second storage unit 750 is a predetermined amount or more, the level sensor may move the working fluid to the second pump 710.

In addition, the power generation system of the present invention may be further formed on the outside of the turbine 30, and may further include a separation unit 900 that partitions the turbine 30 and the generator 800.

The separating part 900 is preferably formed of an insulating plate and prevents high-temperature heat transferred to the turbine 30 from being transmitted to the generator 800.

In addition, the working fluid that has passed through the turbine 30 can be moved only to the first condenser 40 by the separation unit 900 and constitute a closed loop cycle.

A first embodiment of the operation method of the power generation system of the present invention will be described with reference to FIG. 7. 7 is a flow chart showing a first embodiment of the operation method of the power generation system of the present invention.

In the method of operating the power generation system of the present invention, the same configuration as the power generation system of the present invention described above may perform the same or similar functions with the same or similar purposes.

That is, the operation method of the power generation system of the present invention includes a heater 20 for transferring heat to the working fluid, a turbine 30 for converting the thermal energy of the working fluid passing through the heater 20 into mechanical energy, and the turbine 30 ), The first condenser 40 receiving heat from the working fluid passing through, the first pump 10 moving the working fluid passing through the first condenser 40 to the heater 20 and the working fluid Rankine cycle and the turbine 30 provided as a circulation circuit 200 providing a path for circulating the first pump 10, the heater 20, the turbine 30 and the first condenser 40 It is connected to) may be a method of operating a power generation system including a generator 800 for converting mechanical energy into electrical energy.

According to FIG. 7, the operation method of the power generation system of the present invention may include a gas bearing operation step, a turbine 30 operation step, a recovery step, and a condenser flow step.

The gas bearing operation step passes through the first branch circuit 400 that is branched between the heater 20 and the turbine 30 before the working fluid passing through the heater 20 moves to the turbine 30. In order to move to the accommodation space 820 provided adjacent to the generator 800, the working fluid passing through the heater 20 is branched between the heater 20 and the turbine 30 and the first It may be a step of moving to the bypass circuit 500 formed to join the branch circuit 400.

At this time, the operation of the gas bearing is performed when the dryness of the working fluid moving through the first branch circuit 400 is smaller than a preset value to the heating unit 300 installed in the first branch circuit 400. It may include an operation step of heating unit 300 heated by.

It is preferable that the dryness of the working fluid moved through the first branch circuit 400 by the heating unit 300 is maintained at 1. This is the same reason as described above.

The turbine 30 operation step may be a step in which the working fluid passing through the heater 20 moves to at least one of the first branch circuit 400 and the turbine 30 after the gas bearing operation step.

At this time, the operation step of the turbine 30 is moved to the first branch circuit 400 when the pressure of the working fluid passing through the receiving space 820 is lower than the working fluid before passing through the condenser. And a flow control step to increase the amount of working fluid.

The recovery step is a recovery circuit in which the working fluid moving from the first branch circuit 400 joins the circulation circuit 230 provided between the rear end of the turbine 30 and the condenser via the accommodation space 820 ( 600).

At this time, in the recovery step, if the pressure of the working fluid passing through the receiving space 820 is lower than the pressure of the working fluid passing through the turbine 30, at least the working fluid passing through the receiving space 820 Via a second branch circuit 700 which is partly branched from the recovery circuit 600 and formed to join the circulation circuit 240 provided between the first condenser 40 and the first pump 10 And passing through the second branch circuit 700 moving to the first pump 10.

In addition, the step of passing through the second branch circuit 700 is via a second pump 710 installed in the second branch circuit 700 to increase the pressure of the working fluid flowing into the second branch circuit 700. The second pump 710 may include an operation step.

The condenser flow step may be a step in which at least one of the working fluid passing through the turbine 30 and the working fluid passing through the receiving space 820 flows to the condenser.

At this time, the circulation of the working fluid in each circuit such as the circuit 200, the first branch circuit 400, the bypass circuit 500, the recovery circuit 600 and the second branch circuit 700 is not reversed. The circulation circuit 200, the first branch circuit 400, the bypass circuit 500, the recovery circuit 600, and the second branch circuit 700 may include a check valve.

A second embodiment of the operation method of the power generation system of the present invention will be described with reference to FIG. 8. 8 is a flow chart showing a second embodiment of the operation method of the power generation system of the present invention.

In the method of operating the power generation system of the present invention, the same configuration as the power generation system of the present invention described above may perform the same or similar functions with the same or similar purposes.

That is, the operation method of the power generation system of the present invention includes a heater 20 for transferring heat to the working fluid, a turbine 30 for converting the thermal energy of the working fluid passing through the heater 20 into mechanical energy, and the turbine 30 ), The first condenser 40 receiving heat from the working fluid passing through, the first pump 10 moving the working fluid passing through the first condenser 40 to the heater 20 and the working fluid Rankine cycle and the turbine 30 provided as a circulation circuit 200 providing a path for circulating the first pump 10, the heater 20, the turbine 30 and the first condenser 40 It may be a method of operation of the power generation system including a generator 800 for converting mechanical energy into electrical energy connected to).

According to FIG. 8, the operation method of the power generation system of the present invention may include a first branch circuit 400 moving step, a gas bearing activating step, a turbine 30 activating step and a cycle configuring step.

The step of moving the first branch circuit 400 moves the working fluid passing through the heater 20 to the first branch circuit 400 that branches between the heater 20 and the front end of the turbine 30. Can be

In the gas bearing activation step, a working fluid moving from the first branch circuit 400 is provided between the turbine 30 and the condenser via an accommodation space 820 provided adjacent to the generator 800. It may be a step of moving to the recovery circuit 600 joining the circulation circuit 230.

The turbine 30 activation step may be a step in which a portion of the working fluid passing through the heater 20 moves to the turbine 30.

In addition, the cycle configuration step may be a step in which at least one of the working fluid passing through the turbine 30 and the working fluid passing through the receiving space 820 flows to the condenser.

Since at least one of the working fluid passing through the turbine 30 and the working fluid passing through the receiving space 820 flows to the condenser, the power generation system of the present invention can achieve a closed loop cycle.

At this time, the circulation of the working fluid in each circuit such as the circuit 200, the first branch circuit 400, the bypass circuit 500, the recovery circuit 600 and the second branch circuit 700 is not reversed. The circulation circuit 200, the first branch circuit 400, the bypass circuit 500, the recovery circuit 600 and the second branch circuit 700 may include a check valve.

As described above, a preferred embodiment according to the present invention has been examined, and the fact that the present invention can be embodied in other specific forms without departing from the spirit or scope of the embodiment described above has ordinary skill in the art. It is obvious to them. Therefore, the above-described embodiments should be regarded as illustrative rather than restrictive, and accordingly, the present invention is not limited to the above description and may be changed within the scope of the appended claims and their equivalents.

10: first pump
20: burner
30: turbine
40: first condenser
50: first storage unit
200: circuit
210: circulation circuit between the first pump and the heater
220: circulation circuit between the heater and the turbine
230: circulation circuit between the turbine and the first condenser
240: circulation circuit between the first condenser and the first pump
280: initial circuit
290: circulation circuit valve
300: heating unit
400: first branch circuit
500: bypass
600: recovery circuit
610: recovery circuit valve
620: recovery circuit sensor
700: 2nd branch circuit
710: second pump
740: second condenser
750: second storage unit
800: generator
810: rotation axis of the generator
820: accommodation space
830: ball bearing
900: separation

Claims (20)

A heater that transfers heat to the working fluid;
A turbine for converting thermal energy of the working fluid passing through the heater into mechanical energy;
A first condenser that receives heat from a working fluid passing through the turbine;
A first pump for moving the working fluid passing through the first condenser to the heater;
A circulation circuit providing a path for the working fluid to circulate through the first pump, the heater, the turbine, and the first condenser;
A first branch circuit branched from a circulation circuit between the heater and the turbine and at least a portion of a working fluid passing through the heater can move;
A generator connected to the turbine, a gas bearing having an accommodation space formed in communication with the first branch circuit, and a rotating shaft supported by a working fluid passing through the accommodation space;
A recovery circuit in communication with the accommodation space and formed to join the working fluid passing through the accommodation space to a circulation circuit provided at a front end or a rear end of the first condenser; And
A heating unit capable of controlling the dryness of the working fluid flowing into the receiving space by heating the working fluid flowing into the receiving space;
Power generation system comprising a. According to claim 1,
A bypass circuit branched from a circulation circuit between the heater and the turbine, and formed to allow at least a portion of the working fluid passing through the heater to move and join the first branch circuit;
Further comprising,
The power generation system characterized in that the working fluid passing through the heater moves to the bypass circuit before the working fluid passing through the heater moves to the turbine. According to claim 1,
The circulation circuit,
A circulation circuit valve controlling at least one of a flow direction and a flow rate of the working fluid passing through the heater;
Power generation system comprising a. According to claim 1,
The first branch circuit,
The power generation system, characterized in that the working fluid moving the first branch circuit is formed to receive heat from the heater. delete According to claim 1,
The heating unit, the power generation system, characterized in that installed in the first branch circuit. According to claim 1,
The circulation circuit,
A first storage unit provided between the first condenser and the first pump to control the flow rate of the working fluid moving to the first pump;
Power generation system comprising a. According to claim 1,
The generator,
A ball bearing installed in the accommodating space and supporting the rotating shaft of the generator together with the gas bearing;
Power generation system further comprising. According to claim 1,
A second branch circuit branched from the recovery circuit and formed so that at least a portion of the working fluid passing through the accommodation space moves and joins a circulation circuit between the first condenser and the first pump;
Further comprising,
When the pressure of the working fluid passing through the receiving space is lower than the pressure of the working fluid passing through the turbine, at least a portion of the working fluid passing through the receiving space moves to the second branch circuit. . The method of claim 9,
The recovery circuit,
A recovery circuit valve controlling at least one of a flow direction and a flow rate of the working fluid passing through the accommodation space;
Power generation system comprising a. The method of claim 10,
The recovery circuit,
A recovery circuit sensor measuring at least one of temperature and pressure of the working fluid passing through the accommodation space;
Power generation system comprising a. The method of claim 10,
The second branch circuit,
A second pump to increase the pressure of the working fluid flowing into the second branch circuit;
Power generation system comprising a. The method of claim 12,
The second branch circuit,
A second condenser receiving heat from a working fluid moving to the second pump; And
A second storage unit for controlling the flow rate of the working fluid passing through the second condenser;
Power generation system comprising a. According to claim 1,
A separation part formed outside the turbine and partitioning the turbine and the generator;
Power generation system further comprising a. Includes a Rankine cycle and a generator provided with a circulation circuit that provides a path for the heater, turbine, first condenser, first pump and working fluid to cycle through the first pump, the heater, the turbine and the first condenser. In the power generation system,
Before the working fluid passing through the heater moves to the turbine, it passes through the heater so that it can move to a receiving space provided adjacent to the generator via a first branch circuit that branches between the heater and the turbine. A gas bearing operation step in which a working fluid branches between the heater and the turbine and moves to a bypass circuit formed to join the first branch circuit;
After the gas bearing operation step, a turbine operation step in which the working fluid passing through the heater moves to at least one of the first branch circuit and the turbine;
A recovery step in which the working fluid moving from the first branch circuit moves to a recovery circuit joined to a circulation circuit provided between the rear end of the turbine and the first condenser via the accommodation space; And
And a condenser flow step in which at least one of the working fluid passing through the turbine and the working fluid passing through the receiving space flows to the first condenser.
The gas bearing operation step,
And a method of operating a heating unit heated by a heating unit installed in the first branch circuit when the dryness of the working fluid moving through the first branch circuit is smaller than a preset value. delete The method of claim 15,
The recovery step,
When the pressure of the working fluid passing through the receiving space is lower than the pressure of the working fluid passing through the turbine, at least a part of the working fluid passing through the receiving space branches off from the recovery circuit and the first condenser and the first Passing through a second branch circuit moving to the first pump via a second branch circuit formed to be joined to a circulation circuit provided between pumps;
Method of operation of the power generation system comprising a. The method of claim 17,
Step through the second branch circuit,
A second pump operating step installed in the second branch circuit and passing through a second pump that increases the pressure of the working fluid flowing into the second branch circuit;
Method of operation of the power generation system comprising a. The method of claim 15,
The turbine operation step,
A flow rate control step of increasing the amount of working fluid moving to the first branch circuit when the pressure of the working fluid passing through the receiving space is lower than the working fluid before passing through the first condenser;
Method of operation of the power generation system comprising a. Includes a Rankine cycle and a generator provided with a circulation circuit that provides a path for the heater, turbine, first condenser, first pump and working fluid to cycle through the first pump, the heater, the turbine and the first condenser. In the power generation system,
A first branch circuit moving step in which the working fluid passing through the heater moves to a first branch circuit branched between the heater and the front end of the turbine;
A gas bearing activation step of moving a working fluid moving from the first branch circuit to a recovery circuit joined to a circulation circuit provided between the turbine and the first condenser via an accommodation space provided adjacent to the generator;
A turbine activation step in which a portion of the working fluid passing through the heater moves to the turbine; And
It includes; at least one of the working fluid passing through the turbine and the working fluid passing through the receiving space flows to the first condenser;
The gas bearing operation step,
And a method of operating a heating unit heated by a heating unit installed in the first branch circuit when the dryness of the working fluid moving through the first branch circuit is smaller than a preset value.

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