BE1020701A3 - COUPLING OF TURBOPOMPE FOR FILLED SALTS. - Google Patents

Description

TURBOPOMPE COUPLING FOR FILLED SALTS Object of the invention

The present invention relates to the field of combined cycle thermal solar power plants. In particular, the subject of the present application relates to solar concentrating power plant (CSP) plants of the solar tower type, using as heat transfer fluid molten salts and in which are used vertical pumps for the circulation and transfer of melted salts carried at high temperature.

State of the art

In the central tower type CSP, a large number of heliostats (in the form of flat mirrors) reflect sunlight to one or more solar receivers, located at the top of the tower, the heliostats being arranged in such a way that the shadows created by the mirrors do not interfere with neighboring mirrors.

The solar receiver, heated by concentrated incident solar rays will generate a hot fluid which will then be used at ground level to produce high pressure steam capable of driving a turbine and produce electricity.

The heated fluid at the top of the tower may be directly steam, or air, or a thermal oil. But it can also be a molten salt consisting of a mixture of two or three specific salts, or more, used as a heat transfer fluid.

For example, a mixture of sodium nitrate (NaNOs) and potassium nitrate (KNO3) is often used, for example in a 60% / 40% ratio, forming a eutectic at atmospheric pressure having a reduced melting point. at 220 ° C and offering good chemical and thermal stability between melting temperature and 600 ° C. By using a ternary mixture of salts, comprising, besides the two aforementioned salts, lithium nitrate (LiNO 3), it is even possible to obtain a eutectic having a melting point as low as 120 ° C.

A great advantage of this mixture of salts is its possibility of storage in large quantities at high temperature under atmospheric pressure, at a reduced cost. Storage allows the decoupling of solar energy uptake and electricity generation, regardless of sunlight and solar time, including overnight.

The operating principle of a combined cycle CSP plant is known and described for example in WO 2011/077248. FIG. 1 schematically shows the principle of a tower-type concentrating solar power plant 1. The salt is kept liquid in a first insulated cold storage tank 2, at a temperature which is not lower than 260 ° C. Pumps 3 are necessary to bring the molten salt to the top of the tower 1 and given the large flow required and the high density of the salt, the power absorbed by the pumps is quite high, an amplitude of 4 MW for a central high power (typically 150 MW). At the top of the tower, the salt is heated at 550 ° C by concentrated solar heat as specified above via one or more exchangers 20, distributed for example according to four cavities, consisting of thin-walled steel tubes. From there, the heated salt is returned to a second insulated hot storage tank 5. The capacity of this tank depends on the supply time required for the turbine producing the electricity. When the power generation by the plant is required, the hot salt is sent by a pump 6 to a conventional steam generation system 7 to produce superheated steam for a turbine electricity generator 9. FIG. 1 shows also a detailed example, and not limited to the present invention, steam generator 7 according to the state of the art.

The molten salt circuit is referenced 17 and the water / steam circuit is referenced 18 in Figure 1.

Typical performance for a 150 MW installation are given in Table 1.

It is also known that one could use in this type of installation hydraulic power recovery turbines 4 (HRPT for Hydraulic Power Recovery Turbine). These can be installed in the return line of the heated salt to the storage tank, in order to recover the mechanical (gravific) energy of the salt descending from the top of the tower to the ground, the recoverable power having a typical amplitude of 3 MW for the aforementioned plant.

In addition to a number of advantages such as a large storage capacity for energy at atmospheric pressure, a low cost of salt compatible with respect for the environment, a total absence of fire risk , simplicity and reduced costs for the solar receiver and associated equipment at the top of the tower, CSP tower plants have some disadvantages including the need to use very specific pumps, the design of melted salt exchangers / water- steam and the need to monitor the relatively high temperatures of molten salts.

Goals of 11 invention

The present invention aims to overcome the disadvantages of the state of the art.

In particular, the invention aims to reduce the power absorption of heat transfer fluid pumps at the top of the central tower or to compensate it by a power recovery at another location.

Main features of invention

A first object of the present invention relates to a device comprising at least one vertical pump and at least one associated turbine, for transport, on a difference in level, a heat transfer fluid carried at high temperature, the pump ensuring an upward movement of said fluid in a first section of a conduit from a first so-called cold reservoir and the turbine being actuated by said fluid during the downward return movement of said fluid in a second section of the conduit to a second said reservoir; characterized in that the device further comprises a coupling device of the turbine with the pump configured so that the mechanical energy produced by the turbine is reused for the operation of the pump.

According to preferred embodiments of the invention, the device further comprises one or a suitable combination of the following characteristics: the turbine is of the same type as the pump but used in the opposite direction; the coupling device is a mechanical device; the coupling device is an electrical device; the mechanical coupling device comprises a gearbox with a cardan coupling located on the turbine side; the electric coupling device comprises an asynchronous motor coupled to the turbine and acting as a generator, the pump being also actuated by an asynchronous motor; the pump or the turbine is of the type with vertical axis, mono- or multi-stage (multi) cellular with closed or semi-open radial impeller wheels; the pump or turbine is located above the tank or is immersed in body; the pump and the turbine are designed to operate with a mixture of molten salts whose temperature is between 100 and 600 ° C.

A second object of the present invention relates to a solar energy production plant comprising: - a plurality of heliostats arranged on the ground around a central concentration tower, said tower comprising at its summit at minus a heat exchanger; a first circuit for transporting molten salts from a first so-called cold storage tank to said heat exchanger and return to a second so-called hot storage tank for molten salts heated at high temperature, said heat exchanger being at the top of the tower, that is to say at a height greater than that of the tanks; a second steam generation circuit by heat exchange with the first molten salt circuit and generating electricity via a turbine / generator system; characterized in that the installation further comprises the device comprising at least one vertical pump and at least one associated turbine as described above.

[0017] Advantageously, the difference in level between the molten salt storage tanks and the exchangers at the top of the tower is at least 150 m.

Advantageously, the molten salt pressures can be up to 60 bar.

[0019] Preferably, the molten salts include sodium, potassium and / or lithium nitrate.

Brief description of the figures

Exemplary embodiments according to the state of the art and the invention are described later in more detail with the aid of the accompanying figures.

Figure 1, already mentioned, schematically shows a centrally central tower type CSP solar power plant, with circulation of molten salt and coupling to a conventional system of electricity production.

FIG. 2 shows a schematic view of the mechanical coupling system, according to the invention, between the pump for conveying the coolant towards the central tower and the turbine for recovering power at the return of the coolant towards the reservoir of storage.

Description of preferred embodiments of the invention

According to a first preferred embodiment of the present invention, the pumps 3 and the power recovery turbines 4 are mechanically coupled together in order to recover energy with the best possible efficiency.

The type of pump required for the application of molten salt according to the invention is specific. For example, the following characteristics will be found for such pumps: vertical axis; - mono- or multi-stage (multi) cellular construction with closed (or semi-open) wheels; - installation above the salt reservoir, preferably with submerged body, to simplify drainage; - construction with cantilevered shaft possible if the depth of immersion of the pump, that is to say the distance between the seat plate and the suction pipe is sufficiently low; - failing this, the need for intermediate bearings on the shaft line; - shaft sealing with the base plate made by a labyrinth, with return by gravity leaks to the tank; - variable frequency electric motor; - use of materials and construction adequate to withstand the high temperatures of molten salts, etc. The materials used will for example be resistant to corrosion and abrasion.

Such pumps have already been used in the solar field with parabolic collectors on the ground but with relatively low fluid pressures.

The pump must be sized taking into account the following three parameters: its length (about 15 m for example), its variable speed and the high power required.

Advantageously, according to the invention, the power recovery turbines will be of the same design, possibly with specific impeller wheels. In principle, it is sufficient to operate the centrifugal pumps in the opposite direction to be in turbine mode. The mechanical coupling pump-turbine is provided by a gearbox 21, with cardan coupling 41 on the turbine side to allow differential expansion between the pump 3 and the turbine 4.

In the state of the art, we only know coupling systems in-line between horizontal pump and turbine, with clutch.

Of course, the turbines 4 can not recover all the power consumed by the pumps, given the efficiency of the pumps and turbines, playing in opposite directions.

Still according to the invention, the compensation of the power difference will be provided by electric pumps of the same type (not shown), moreover necessary to overcome the pressure losses and also to start the system.

According to a second preferred embodiment of the present invention, the pumps 3 and the recovery turbines 4 will be electrically coupled. The pumps 3 are actuated by an asynchronous motor and the turbines are coupled to an asynchronous motor also acting as a generator, the turbine engine being faster.

List of marks 1 Solar Concentration Tower 2 Cold Salt Tank 3 Feed Pump to Tower 4 Recovery Turbine 5 Hot Salt Tank 6 Flow Pump to Steam Generator 7 Steam Generator 8 Turbine (s) 9 Generator of electricity 10 Condenser 11 Deaerator 12 Economizer 13 Kettle boiler 14 Superheater 15 Resuperheater 16 Mixing pump 17 Molten salt circuit 18 Water / steam circuit 20 Solar receivers and exchangers 21 Gearbox 41 Cardan shaft

Claims (13)

1. Device comprising at least one vertical pump (3) and at least one associated turbine (4), for the transport, on a difference in level, of a heat transfer fluid carried at high temperature, the pump (3) providing a movement ascending said fluid in a first section of a conduit (17) from a first so-called cold reservoir (2) and the turbine (4) being actuated by said fluid during the downward return movement of said fluid in a second section of the conduit (17) to a second so-called hot reservoir (5), characterized in that the device further comprises a device for coupling the turbine (4) with the pump (3) configured so that the mechanical energy produced by the turbine (4) is reused for the operation of the pump (3). 2. Device according to claim 1, characterized in that the turbine (4) is of the same type as the pump (3) but used in the opposite direction. 3. Device according to claim 1, characterized in that the coupling device is a mechanical device (21, 41). 4. Device according to claim 1, characterized in that the coupling device is an electrical device. 5. Device according to claim 3, characterized in that the mechanical coupling device comprises a gearbox (21) with a cardan coupling (41) located on the turbine side (4). 6. Device according to claim 4, characterized in that the electrical coupling device comprises an asynchronous motor coupled to the turbine (4) and acting generator, the pump (3) is also actuated by an asynchronous motor. 7. Device according to claim 2, characterized in that the pump (3) or the turbine (4) is of the vertical axis type, mono- or multi-stage (multi) cellular with closed or semi-open radial impeller wheels. . 8. Device according to claim 7, characterized in that the pump (3) or the turbine (4) is located above the tank or is immersed body. 9. Device according to claim 1, characterized in that the pump (3) and the turbine (4) are designed to operate with a mixture of molten salts whose temperature is between 10O and 600 ° C. Solar energy production plant comprising: - a plurality of heliostats disposed on the ground around a central tower (1) of concentration, said tower comprising at its summit at least one heat exchanger (20); a first circuit (17) for transporting molten salts from a first so-called cold storage tank (2) to said heat exchanger (20) and back to a second so-called hot storage tank (5) for molten salts carried at high temperature, said exchanger (20) being at the top of the tower (1), that is to say at a height greater than that of the tanks (2, 5); - a second circuit (18) for steam generation by heat exchange with the first circuit (17) molten salt and electricity production via a turbine / generator system (7, 8, 9); characterized in that the installation further comprises the device comprising at least one vertical pump (3) and at least one associated turbine (4) according to any one of the preceding claims. 11. Installation according to claim 10, characterized in that the difference in level between the molten salt storage tanks (2, 5) and the exchangers (20) at the top of the tower is at least 150 m. 12. Installation according to claim 10, characterized in that the molten salt pressures can be up to 60 bar. 13. Installation according to claim 10, characterized in that the molten salts include sodium nitrate, potassium and / or lithium.