SOLAR POWER GENERATING SYSTEM AND THE METHOD OF GENERATING ELECTRICITY AND PROVIDING HEAT IN SUCH A SYSTEM

Abstract

A solar power generating system for generating electricity and providing heat includes; at least one generator for generating the electricity; a heating element for heating a heat transfer fluid; a turbocharger having at least one turbocharger turbine and at least one turbocharger compressor, wherein the at least one turbocharger compressor is adapted to receive and pressurize the heat transfer fluid, and the at least one turbocharger turbine is coupled to the at least one turbocharger compressor, wherein the at least one turbocharger compressor receiving and expanding a heated compressed heat transfer fluid coming from the heating element to drive the at least one turbocharger compressor and; a control unit configured to control the solar power generating system by comparing thermophysical properties obtained from more than one sensors placed in the solar power generating system with predetermined data in the control unit.

Claims

1. A solar power generating system for generating electricity and providing heat comprising; at least one generator for generating the electricity; a heating element for heating a heat transfer fluid; a turbocharger comprising at least one turbocharger turbine and at least one turbocharger compressor, wherein the at least one turbocharger compressor is adapted to receive and pressurize the heat transfer fluid to obtain a heated compressed heat transfer fluid, and the at least one turbocharger turbine is coupled to the at least one turbocharger compressor, wherein the at least one turbocharger compressor is configured to receive and expand the heated compressed heat transfer fluid coming from the heating element to drive the at least one turbocharger compressor and; a control unit configured to control the solar power generating system by comparing thermophysical properties obtained from more than one sensor placed in the solar power generating system with predetermined data in the control unit, wherein the at least one generator configured as a starter generator for supplying a power to operate a power turbine at a startup mode wherein the startup mode is an intermediate transition stage between a stationary state of the solar power generating system and a power generation mode; the power turbine in communication with an inlet of the solar power generating system, wherein the power turbine is configured to work as a compressor at the start up mode wherein the power turbine is configured to rotate with the starter generator at a same speed wherein the starter generator is mechanically connected with the power turbine; and a compressor bypass valve is configured for controlling a flow rate of the heat transfer fluid and routing the heat transfer fluid to the heating element by allowing the heat transfer fluid to bypass the at least one turbocharger compressor at the start up mode.

2. The solar power generating system according claim 1, wherein the starter generator is configured to supply the power to the power turbine until the starter generator reaches a predetermined speed corresponding to a predefined algorithm in the control unit at the start up mode.

3. The solar power generating system according to claim 2, wherein the power turbine provided at the inlet of the solar power generating system is connected with the starter generator and located in a region before the heat transfer fluid enters the at least one turbocharger compressor.

4. The solar power generating system according to claim 1, wherein the heat transfer fluid routed from a power turbine outlet is injected to either the heating element or the at least one turbocharger compressor in the solar power generating system.

5. The solar power generating system according to claim 1, wherein the solar power generating system is configured to recirculate the heat transfer fluid to the power turbine.

6. The solar power generating system according to claim 3, wherein the heating element is at least one solar collector.

7. The solar power generating system according to claim 3, wherein the heating element is at least one heat exchanger.

8. The solar power generating system according to claim 7, wherein the at least one heat exchanger is configured to utilize the heat obtained from at least one external heat source.

9. The solar power generating system according to claim 6, further comprising a second heat exchanger positioned at an outlet of the heating element and/or an outlet of the at least one turbocharger turbine for providing the heat outside of the solar power generating system.

10. The solar power generating system according to claim 3, wherein the heating element further comprises a heat transfer enhancement material.

11. The solar power generating system according to claim 10, wherein the heat transfer enhancement material is a foam made of a metal.

12. The solar power generating system according to claim 3, wherein the heat transfer fluid is an ambient air.

13. The solar power generating system according to claim 1, wherein the heat transfer fluid is a non-corrosive and non-flammable gas.

14. The solar power generating system according to claim 1, wherein the power turbine is mechanically connected with a power generator shaft and aerodynamically coupled with the turbocharger.

15. The solar power generating system according to claim 1, further comprising pipes and cavities for transmitting the heat transfer fluid to more than one element of the solar power generating system.

16. A method of generating electricity and providing heat in a solar power generating system comprising a start up mode and a power generating mode, wherein the start up mode further comprising the steps of: requiring the electricity from a battery or a grid to a starter generator to rotate a power turbine; increasing a pressure of a heat transfer fluid to the power turbine configured to work as a compressor at the start up mode to obtain a compressed heat transfer fluid; channeling a power turbine outlet heat transfer fluid to a heating element to increase a temperature; routing the compressed heat transfer fluid heated by the heating element to a turbocharger turbine, wherein the turbocharges turbine drives a turbocharger compressor; controlling and adjusting a flow rate of the compressed heat transfer fluid via at least one valve continuously in the solar power generating system by a control unit; wherein a power generation mode further comprising the steps of: passing the heat transfer fluid through the power turbine causing the power turbine to rotate; rotating the starter generator by the power turbine to generate the electricity; transferring the heat transfer fluid to the turbocharger compressor for increasing the pressure; pressurizing the heat transfer fluid by the turbocharger compressor to obtain the compressed heat transfer fluid; channeling the turbocharger compressor outlet heat transfer fluid to the heating element for increasing the temperature of the compressed heat transfer fluid; directing the compressed heat transfer fluid heated by the heating element to the turbocharger turbine; expanding the compressed heat transfer fluid heated by the heating element in the turbocharger turbine for driving the turbocharger compressor; controlling and adjusting the flow rate of the compressed heat transfer fluid via the at least one valve continuously in the solar power generating system by the control unit.

17. The method according to claim 16, wherein the start up mode further comprising the step of discharging the heat transfer fluid by partially sending to the turbocharger compressor for compensating an excess suction, wherein the excess suction is determined by predetermined data in the control unit.

18. The method according to claim 16, further comprising the step of recirculating, at least partially, from a turbocharger turbine outlet to the power turbine inlet.

19. The method according to claim 16, further comprising the step of obtaining the heat from a heat exchanger configured to provide the heat from an external heat source.

20. The method according to claim 16, further comprising the step of providing the heat in the solar power generating system by directly ejecting the heat transfer fluid from an heating element outlet and/or a turbocharger turbine outlet for providing the heat for external applications requiring use of the heat.

21. The method according to claim 16, further comprising the step of providing the heat in the solar generating system by using a heat exchanger from an heating element outlet and/or a turbocharger turbine outlet for providing the heat for external applications requiring use of the heat.

22. The solar power generating system according to claim 1, wherein the solar power generating system is configured to generate the electricity for electrical grid.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0014] The figures, whose brief explanations are herewith provided, are solely intended for providing a better understanding of the present invention and are as such not intended to define the scope of protection or the context in which said scope is to be interpreted in the absence of the description.

[0015] FIG. 1 illustrates a schematic view of the solar power generating system.

[0016] FIG. 2 illustrates a schematic view of the power generation mode according to the present invention.

[0017] FIG. 3 illustrates a schematic view of the start up mode according to the present invention.

[0018] FIG. 4 illustrates the flow directions for heat transfer fluid in the power generation mode according to the present invention.

[0019] FIG. 5 illustrates the flow directions for heat transfer fluid in the start up mode according to the present invention.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0020] Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings which are given solely for the purpose of exemplifying embodiments according to the present invention. The list of reference numerals used in the appended drawings are as follows;

REFERENCE NUMBERS

[0021] 100. Solar power generating system [0022] 102. Starter generator [0023] 110. Power generator shaft [0024] 120. Power turbine [0025] 130. Heating element [0026] 140. Compressor bypass valve [0027] 150. Turbocharger [0028] 151. Turbocharger turbine (TT) [0029] 152. Turbocharger compressor (TC) [0030] 160. Turbocharger shaft [0031] 170. Valve [0032] 171. Bearing [0033] 172. Power turbine inlet pipe [0034] 173. Heating element inlet pipe [0035] 174. Heating element outlet pipe [0036] 175. Turbocharger compressor inlet pipe [0037] 176. Turbocharger compressor outlet pipe [0038] 177. Turbocharger turbine outlet pipe [0039] 178. Recirculation pipe [0040] 180. Control unit [0041] 181. Inlet [0042] 182. Outlet [0043] D: Dashed lines represent the transmission of data from the thermophysical (i.e. temperature, pressure, humidity, speed) sensors to control unit (180) and the signals of the commands given to the valve (170) from the control unit (180). [0044] E: Dashed line represents the bleeding heat transfer fluid channeling by partially sending the heat transfer fluid to the turbocharger compressor inlet pipe (175) for preventing the turbocharger damage by the excess suction.

[0045] The present invention proposes a solar power generating system (100) for generating electricity and providing heat comprising at least one generator (102) for producing electricity; a heating element (130) for heating the heat transfer fluid; a turbocharger (150) having at least one turbocharger turbine (151) and at least one turbocharger compressor (152), wherein said turbocharger compressor is (152) adapted to receive and pressurize the heat transfer fluid, and said turbocharger turbine (151) coupled to the turbocharger compressor (152), which receiving and expanding the heated compressed heat transfer fluid coming from the heating element (130) to drive the turbocharger compressor (152) and; a control unit (180) configured to control the solar power generating system (100) by comparing thermophysical properties obtained from sensors placed in different stages of the solar power generating system (100) with predetermined data into a control unit (180), wherein said solar power generating system (100) further comprises said generator (102) configured to work as a starter generator (102) for supplying power to operate the solar power generating system (100) at a start up mode; a power turbine (120) in communication with the inlet (181) of the solar power generating system (100), such that said power turbine (120) is configured to work as a compressor at start up mode wherein said power turbine (120) is configured to rotate the same speed of the starter generator (102) which is mechanically connected with said power turbine (120); and a compressor bypass valve (140) for controlling the flow rate of the heat transfer fluid and routing the heat transfer fluid to the heating element (130) by allowing the heat transfer fluid to bypass the compressor (152) at the start up mode.

[0046] In an embodiment of the present invention, the power turbine (120) provided at the inlet (181) of the solar power generating system (100) is connected with the starter generator (102) and can be located in a region before the heat transfer fluid enters the turbocharger compressor (152) in the solar power generating system (100). Referring to FIG. 1, installing the power turbine (120) at the inlet (181) of the solar power generating system (100) provides cold heat transfer fluid to generate power having several advantages, such that heat transfer fluid does not cause high thermal expansion and provides low clearance variation between hot and cold cases. The low temperature of the power turbine (120) can be referred as a creeping temperature which is approximately 0.4 times of the absolute melting temperature of the material from which the power turbine (120) is made. The temperature range in which creep deformation may occur differs in various materials such that said creeping temperature changes according to the material of the power turbine (120). The power turbine (120) can be aerodynamically coupled with different rotatable shafts of the power generator shaft (110) and shaft of the turbocharger that allows to run the turbocharger (150) at predetermined point and optimize the power turbine (120) for desired speed without using any reducer or gearbox. Said shafts can be used as a rotating machine elements, usually circular in cross section, for transmitting power from one part to another.

[0047] Using mass produced turbocharger (150) (i.e car turbocharger) makes the solar power generating system (100) cheaper and the heating element (130) can be optimized depending on the installation location and turbomachinery characteristics for the power generation.

[0048] According to the present invention, the power turbine (120) is configured to run as a compressor at predetermined low speeds which are below required electricity generation speed of the starter generator (102). Power required to rotate the power turbine (120) is supplied from the starter generator (102) until the starter generator reaches a predetermined speed corresponding to a predefined algorithm at the control unit at the start up mode. Moreover, the power turbine (120) can be mechanically connected with a power generator shaft (110) and aerodynamically coupled with the turbocharger (150).

[0049] According to the present invention, the solar power generating system (100) also comprises pipes and cavities for transmitting the heat transfer fluid to more than one element of the solar power generating system (100) and also if required further comprising cooling the bearing lubrication oil among elements. As shown in FIG. 2 and FIG. 3, said pipes are used as a power turbine inlet pipe (172) to supply the heat transfer fluid to the power turbine (120); a heating element inlet pipe (173) is used to route the heat transfer fluid to the heating element (130) after discharged from the power turbine (120); a heating element outlet pipe (174) to route the heat transfer fluid to the turbocharger turbine (151); a turbocharger compressor inlet pipe (175) to transfer the heat transfer fluid from power turbine (120) to the turbocharger compressor (152); a turbocharger compressor outlet pipe (176) to transfer the heat transfer fluid from turbocharger compressor (152) to the heating element (130); a turbocharger turbine outlet pipe (177) to route the heat transfer fluid to the outlet (182), and a recirculation pipe (178) to recirculate flow to the power turbine (120) again.

[0050] According to the present invention, the turbocharger (150) comprises the turbocharger turbine (151) and the turbocharger compressor (152), wherein the turbocharger compressor (152) is adapted to receive and pressurize the heat transfer fluid and said turbocharger turbine (151) is coupled to the turbocharger compressor (152). Said turbocharger turbine (151) supplies sufficient power to drive the turbocharger compressor (152), likewise said turbocharger compressor (152) pressurizes the heat transfer fluid and then routes heat transfer fluid to the heating element (130). The heat transfer fluid coming from the power turbine outlet can be injected to either the heating element (130) or the turbocharger compressor (152) in the solar power generating system (100). Referring FIG. 4, upstream of the power turbine (120) heat transfer fluid can be premixed with a turbocharger turbine outlet for preheat before passing the heating element (130). In one embodiment, the turbocharger (150) further comprising a turbocharger shaft (160) for transmitting the power from the turbocharger turbine (151) to turbocharger compressor (152) as well.

[0051] Another feature of the invention is that the solar power generating system (100) comprises the compressor bypass valve (140), wherein said compressor bypass valve (140) can be a kind of a flow-regulating valve that primarily works at the start up mode, such that this valve allows the heat transfer fluid to bypass the compressor (152) and routes the heat transfer fluid directly to the heating element (130) at low speed of the turbocharger shaft (160), which are gradually closed with increasing turbocharger speed, and finally it is fully closed at power generation mode according to the present invention.

[0052] In different embodiments of the invention, the heating element (130) may be configured as a solar collector (130) for utilizing solar energy or a heat exchanger (130) configured to utilize of heat obtained from at least one external heat source; moreover, said heat exchanger (130) providing utilization of excess process heat from another system allows to increase temperature of heat transfer fluid in various industrial heat application processes. The solar power generating system (100) further can have a second heat exchanger positioned at an outlet of the heating element (130) and/or an outlet of the turbocharger turbine (151) for providing heat outside of the solar power generating system (100).

[0053] In another possible embodiment, said solar collector (130) can contain inner heat transfer enhancement material placed inside an absorber tube where the sun is focused on the solar collector for increasing the heat transfer rate to the heat transfer fluid and also this material can be such as metal foam, twisted types or inner fins.

[0054] A method of generating electricity and providing heat in the solar power generating system (100) comprising the start up mode and a power generation mode. In the start up mode, the starter generator (102) supplies required torque to the power generator shaft (110). The start up mode further comprises the steps of requiring electricity from battery or grid to the starter generator (102) to rotate the power turbine (120), increasing pressure of the heat transfer fluid to the power turbine (120) configured to work as a compressor at the start up mode, channeling the power turbine outlet heat transfer fluid to the heating element (130) to increase the temperature, routing the compressed heat transfer fluid heated by the heating element (130) to the turbocharger turbine (151) which drives the turbocharger compressor (152), controlling and adjusting a flow rate of the heat transfer fluid via at least one valve (170) continuously in the solar power generating system (100) by the control unit (180) as shown in FIG. 5 where the dashed line represents the fluid passing through the flow in small quantities and increases with increasing turbocharger shaft (160) speed by regulating compressor bypass valve (140). In the start up mode, for controlling the system, correlations can be generated using pressure, temperature and shaft speeds using the sensors installed at specific locations in the system.

[0055] In power generation mode, referring to the FIG. 2 and FIG. 4, the heat transfer fluid passes through the power turbine (120) for electricity generation and driving pressure difference of the heat transfer fluid is the suction created by the turbocharger compressor (152) at the power turbine (120) outlet which is driven by the turbocharger turbine (151) coupled with the turbocharger shaft (160). Said power generation mode comprises the steps of passing heat transfer fluid through the power turbine (120) which causes to the power turbine (120) rotate, rotating the starter generator (102) by power turbine (120) to generate electricity, transferring the heat transfer fluid to the turbocharger compressor (152) for increasing the pressure, pressurizing the heat transfer fluid by the turbocharger compressor (152), channeling the heat transfer fluid by the turbocharger compressor outlet pipe (176) to the heating element (130) for increasing the temperature, directing the compressed heat transfer fluid heated by the heating element (130) to the turbocharger turbine (151), expanding the compressed heat transfer fluid heated by the heating element (130) in the turbocharger turbine (151) for driving the turbocharger compressor (152), controlling and adjusting a flow rate of the heat transfer fluid via at least one valve (170) continuously in the solar power generating system (100) by the control unit (180). In other words, rotational energy required for the starter generator (102) is provided by the power turbine (120) at the inlet of the solar power generating system (100) in power generating mode. After reaching of electricity generation speed limit of the starter generator (102), said starter generator (102) can convert to generate power and works as a power generator (102). For both start up and the power generation mode, a correlation can be generated for the solar power generating system (100) control using pressure and temperature sensors at specific locations.

[0056] The power generator shaft (110) further can be used to transmit power between the starter generator (102) and the power turbine (120) in the solar power generating system (100). The flow direction and the amount of heat transfer fluid can be controlled with the valves (170), nozzles and diffuser or such other similar functioning elements. According to the present invention, the solar power generating system (100) may comprise at least two bearings (171) located in the each power generator shaft (110) and turbocharger shaft (160) to support the rotating parts. Various elements locations such as bearings (171), the heating element outlet and the turbocharger turbine outlet can provide the excess heat, in which are utilized hot water or steam generation if desired by using heat exchanger or other heat transfer methods. In addition, heat transfer fluid can be directly ejected from the system for hot fluid use as explained above from the heating element outlet and the turbocharger turbine outlet.

[0057] According to the present invention, when the sun rises and DNI (Direct Normal Insolation) passes the limiting value for the start up mode, the solar collector (130) starts orienting by the grid power or a battery. After tracking starts, the starter generator (102) powers, the power turbine (120); majority of the fluid is routed directly to the solar collector (130) passing through the compressor bypass valve (140), the gradually temperature of the heat transfer fluid discharged from a solar collector (130) rises. For preventing the excess suction or possible turbocharger damage, partially heat transfer fluid also can be sent to the turbocharger compressor (152) for pressure balance. The heat transfer fluid discharged from the solar collector passes through the turbocharger turbine (151); moreover, some amount of the heat transfer fluid outlet from turbine (151) can route to the turbocharger compressor (152) and/or power turbine (120) for preheating.

[0058] In another embodiment of the system, the control unit (180) is configured to control the solar power generating system (100) by comparing thermophysical properties obtained from sensors placed in the solar power generating system (100) with predetermined data into the control unit (180). Thermophysical properties can be simply defined as material properties that vary with temperature without altering the material's chemical identity such that said sensors can vary according to the desired amount and type. By obtaining data of temperature, pressure, humidity, direct normal irradiance (DNI), wind of ambient condition, speed of shafts and supplied or generated electricity values such as current, voltage or phase; the control unit (180) actuates valves (170) and other controllable elements for operating the system in desired conditions. In different embodiments, said control unit (180) can also regulate the tracking of the solar collector (130) or an additional controller can be used for tracking the sun. The starter generator (102) and valves (170) can be used in controlling mass flow, by reading temperature and pressure sensor obtaining data from the heating element inlet and outlet when compare with predetermined values centered in control unit (180).

[0059] According to the present invention, the solar power generating system (100) can be designed as an open or closed cycle. As an open cycle of both start up and power generation modes; in the last step, ambient air used as heat transfer fluid exits the turbocharger turbine (151) and leaves the solar power generating system (100) from the outlet (182). A new fresh heat transfer fluid is being fed from the power turbine (120) for a new cycle. The heat transfer fluid discharged from the turbocharger turbine (151) is disposed to ambient at the outlet (182) or partly routed to power turbine inlet pipe (172) of the solar power generating system (100) according to the different embodiments of the invention. During operation, as an open cycle, solar power generating system (100) can dispose all the heat transfer fluid to outlet (182), or recirculate all the heat transfer fluid to the power turbine (120) via recirculation pipe (178) or partially dispose and partially recirculate. On the contrary, as the close cycle design of both start up and power generation modes, the heat transfer fluid coming from the turbocharger turbine outlet is routed to directly power turbine inlet for a continuous process. The heat transfer fluid might be any of compressible fluid such as air, a non corrosive and non-flammable gas if the system is close cycle.

[0060] In a further embodiment of the present invention, which does not contain combustor, heat transfer fluid can be recirculated, which allows to operate as close cycle, even solar power generating system (100) is designed as an open cycle using valve (170).

[0061] The said solar power generating system (100) and method can be applied to residential, industrial applications as on or off-grid conditions. Electrical grids are an interconnected network for delivering electricity from producers to consumers.