JP2017067359A - Steam generation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a novel heat storage method.SOLUTION: A steam generation device 1 has a sunlight collection device 2 for heating a fluid by sunlight and a gas-liquid drum 31 for storing steam and a liquid of the fluid, and the fluid continuously circulates between the two. The gas-liquid drum 31 is connected to an external facility 9 by a steam supply passage 41. A pressure adjustment part 42 fluctuates an internal pressure while supplying the steam to the external facility 9 by cutting off passing of the steam in the steam supply passage 41 in the case where the internal pressure of the gas-liquid drum 31 is below a setting pressure set for using the steam in the external facility 9, and by allowing the steam to pass in a throttle part in which a flow passage area is partially reduced in the steam supply passage 41 in the case where the internal pressure is equal to or greater than the setting pressure. Thereby, in the case where the amount of solar radiation is large, heat can be stored in the gas-liquid drum 31 while supplying the steam to the external facility 9, so that even in the case where the amount of solar radiation is small, steam can be supplied to the external facility 9 for a certain period.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a steam generator using sunlight.

  In recent years, a technique for collecting solar thermal energy by concentrating sunlight and heating a heat medium has been put into practical use. In the steam generation apparatus according to the technology, steam is generated using concentrated sunlight, and the steam is used for various purposes.

  On the other hand, solar radiation, which is a heat source, varies depending on the weather, time zone, and the like. Therefore, in the solar thermal power generation system of Patent Document 1, a heat storage device and an accumulator are provided, and when the amount of sunlight is small and the temperature at the collector outlet is equal to or lower than a certain temperature, a liquid heat collection medium is sent to the accumulator. . When the pressure in the accumulator becomes equal to or higher than a certain pressure, saturated steam generated in the accumulator is converted into superheated steam through the heat accumulator and sent to the turbine. Further, when the amount of sunshine increases and the temperature at the collector outlet sufficiently rises, the steam of the heat collection medium is sent directly to the heat accumulator and further to the turbine. At this time, when the temperature of the steam is higher than the heat storage temperature of the heat storage device, heat is supplied to the heat storage material of the heat storage device.

  In the apparatus of Patent Document 2, water in the evaporator pipe of the heat absorber is heated by solar energy and stored as steam in a brackish water drum. Steam is supplied to a power generation turbine or stored in a heat storage tank. Further, a steam flow rate adjusting valve for adjusting the steam flow rate from the heat storage tank to the brackish water drum is provided, and the steam flow rate regulating valve is controlled so that the temperature gradient of the brackish water drum becomes constant when the heat absorber is activated. Moreover, when the pressure of the brackish water drum becomes a predetermined pressure, the flow rate of the steam sent from the brackish water drum to the heat storage tank or the load side is controlled so that the pressure of the brackish water drum becomes a predetermined value.

  Patent Document 3 discloses a pressure control device that detects the steam pressure of a brackish drum and compares it with a set value, and controls the flow rate of steam supplied from the brackish drum to a load, thereby maintaining the braided drum pressure at the set value. Has been. Also disclosed is a method for stabilizing the steam flow rate by increasing the pressure set value when the steam flow rate is increasing and decreasing the pressure set value when the steam flow rate is decreasing. . Also in the apparatus of Patent Document 3, a pressure water tank as a heat accumulator is arranged on the load side.

JP-A-53-59155 JP 58-160703 A Japanese Patent Publication No. 61-8323

  By the way, in the apparatus of patent documents 1 thru | or 3, in order to perform heat storage, since a thermal storage (a thermal storage tank is included) becomes an essential component, a fixed restriction | limiting arises in the design of a steam generator, etc. Therefore, a new heat storage method that can omit the heat storage device is required.

  This invention is made | formed in view of the said subject, and aims at providing the novel thermal storage technique.

  The invention according to claim 1 is a steam generating device that uses sunlight, a solar light collecting device that heats a fluid by the concentrated sunlight, and a gas-liquid that stores the fluid vapor and liquid. A drum, a pump for continuously circulating the fluid between the solar light collecting device and the gas-liquid drum, a vapor supply path connecting the gas-liquid drum and external equipment, and the gas-liquid drum When the internal pressure is less than a set pressure set for using the steam in the external equipment, the steam is blocked from passing through the steam supply path, and the internal pressure is equal to or higher than the set pressure. In some cases, a pressure adjusting unit that varies the internal pressure while supplying the steam to the external equipment by allowing the steam to pass through a throttle portion in which the flow path area is partially reduced in the steam supply path, Is provided.

  Invention of Claim 2 is the steam generator of Claim 1, Comprising: When the said internal pressure becomes more than the upper limit pressure higher than the said setting pressure, the said pressure adjustment part is the said steam supply path The internal pressure is maintained at approximately the upper limit pressure by adjusting the area of the flow path through which the steam passes.

  Invention of Claim 3 is a steam generator of Claim 2, Comprising: The said pressure adjustment part is provided with the pressure control valve provided in the said steam supply path, The said internal pressure is more than the said upper limit pressure In such a case, when the opening degree of the pressure control valve is adjusted and the internal pressure is not less than the set pressure and less than the upper limit pressure, the pressure control valve functions as the throttle portion.

  Invention of Claim 4 is a steam generator in any one of Claim 1 thru | or 3, Comprising: The said upper limit pressure is 2 times or more of the said setting pressure.

  A fifth aspect of the present invention is the steam generator according to any one of the first to fourth aspects, wherein no steam accumulator is provided in the steam supply path.

  A sixth aspect of the present invention is the steam generator according to any one of the first to fifth aspects, wherein the external equipment is provided with an auxiliary boiler that generates steam with fuel.

  According to the present invention, heat can be stored in the gas-liquid drum while supplying steam to the external equipment when the amount of solar radiation is large, and steam can be supplied to the external equipment for a certain period even when the amount of solar radiation is small. it can.

It is a figure which shows the structure of a steam generator. It is a figure which shows the structure of a sunlight condensing device. It is a figure which shows the flow of operation | movement of a pressure adjustment part.

  FIG. 1 is a diagram showing a configuration of a steam generator 1 according to an embodiment of the present invention. The steam generator 1 is a device that generates steam using sunlight, and is a direct steam generation type device that directly generates water steam without using another heat medium. The steam generator 1 is used, for example, in a seawater desalination plant (fresh water plant) that generates fresh water by steam heating of seawater.

  The steam generator 1 includes a solar light collecting device 2, a gas-liquid drum 31, a pump 32, a steam supply path 41, and a pressure adjustment unit 42. The gas-liquid drum 31 is a brackish water drum for storing water vapor and liquid as a heat medium. The gas-liquid drum 31 is provided with a circulation path 33 for circulating water between the solar light collecting device 2. The pump 32 is provided in a portion of the circulation path 33 from the gas-liquid drum 31 toward the solar light collecting device 2. The pump 32 feeds liquid water existing below the gas-liquid drum 31 to the solar light collector 2 at an approximately constant flow rate, and passes through the solar light collector 2 (for example, water Steam) returns to the gas-liquid drum 31. In this way, the pump 32 continuously circulates water along the circulation path 33 that connects the gas-liquid drum 31 and the solar light collecting device 2.

  In the circulation path 33, a pressure sensor 331, a valve (check valve) 332, a valve 333, and a temperature sensor 334 are provided between the pump 32 and the solar light collecting device 2. The pressure sensor 331 measures the pressure of water due to the liquid feeding of the pump 32. The temperature sensor 334 measures the temperature of water immediately before flowing into the solar light collecting device 2. For example, in the circulation path 33, another path arranged in parallel is provided for a portion including the combination of the pump 32, the pressure sensor 331, and the check valve 332, and the same combination as the above combination is provided in the path. May be. In this case, during the maintenance of one pump 32, the steam generator 1 can be continuously operated using the other pump 32 (the same applies to the pump 521 described later).

  The gas-liquid drum 31 is provided with a pressure sensor 422 and a level sensor 311. The pressure sensor 422 is a part of the pressure adjusting unit 42, and the internal pressure (steam pressure) of the gas-liquid drum 31 is measured by the pressure sensor 422. The level sensor 311 measures the position of the liquid level in the gas-liquid drum 31. One end of a steam supply path 41 is connected to the upper part of the gas-liquid drum 31.

  The steam supply path 41 connects the gas-liquid drum 31 and the external equipment 9. When the steam generator 1 is used in a seawater desalination plant, the external equipment 9 includes a seawater heater and the like, and the steam supply path 41 is connected to the heater. The external equipment 9 has an auxiliary boiler 91 that generates steam with fuel, and can supply the steam from the auxiliary boiler 91 to the heater. Information such as measured values of each sensor in the steam generator 1 is input to a control unit (not shown) of the external equipment 9, and the auxiliary boiler 91 and the like are controlled according to the information.

  In the steam supply path 41, a pressure control valve 421, a temperature sensor 411, a pressure sensor 412, and a flow rate sensor 413 are provided in order from the gas-liquid drum 31 toward the external equipment 9. The temperature, pressure, and flow rate of the steam flowing through the steam supply path 41 are measured by the temperature sensor 411, the pressure sensor 412, and the flow rate sensor 413, respectively. The pressure control valve 421 is a part of the pressure adjustment unit 42. The pressure adjustment unit 42 further includes an internal pressure control unit 423. In the pressure adjustment unit 42, the measurement value of the internal pressure of the gas-liquid drum 31 acquired by the pressure sensor 422 is input to the internal pressure control unit 423, and the pressure control valve 421 is activated according to the measurement value by the internal pressure control unit 423. Be controlled. Details of the control of the pressure control valve 421 in the pressure adjusting unit 42 will be described later.

  The steam generator 1 further includes a water supply tank 51, a water supply path 52, and a water supply flow rate control unit 53. The water supply tank 51 stores water for water supply. The water supply path 52 connects the water supply tank 51 to the circulation path 33. Specifically, one end of the water supply path 52 is connected to the water supply tank 51, and the other end is connected between the pump 32 and the solar light collector 2 in the circulation path 33. The other end of the water supply path 52 may be connected between the gas-liquid drum 31 and the pump 32 in the circulation path 33 or to the gas-liquid drum 31 itself. In the water supply path 52, a pump 521, a pressure sensor 522, a valve (check valve) 523, a temperature sensor 524, a flow sensor 525, and a flow control valve 526 are provided in order from the water supply tank 51 toward the circulation path 33. The pressure sensor 522 measures the pressure of water due to the liquid feeding by the pump 521. The temperature sensor 524 and the flow rate sensor 525 measure the temperature and flow rate of the water flowing through the water supply channel 52, respectively.

  A measured value of the flow rate of the steam flowing through the steam supply path 41 and a measured value of the liquid surface position in the gas-liquid drum 31 are input to the feed water flow rate control unit 53 from the flow rate sensor 413 and the level sensor 311, respectively. Based on these measured values, the feed water flow rate control unit 53 controls the flow rate control valve 526 so that the position of the liquid level in the gas-liquid drum 31 is constant.

  FIG. 2 is a diagram illustrating a configuration of the solar light collecting device 2. The solar light collecting device 2 is a so-called Fresnel type light collecting device, and heats water with the concentrated sunlight. The solar light collecting device 2 includes a large number of mirrors 21 and a heat recovery tube 22. The water sent from the gas-liquid drum 31 by the pump 32 flows inside the heat recovery pipe 22, and a large number of mirrors 21 concentrate the sunlight on the heat recovery pipe 22, whereby the heat recovery pipe 22. The water inside is heated. The temperature of the water that has passed through the heat recovery pipe 22 is measured by the temperature sensor 23. The water heated by the solar light collecting device 2 is returned to the gas-liquid drum 31 through the circulation path 33. In the preferable steam generator 1, a plurality of solar light collecting devices 2 are provided, and water is heated by the plurality of solar light collecting devices 2. The sunlight concentrating device 2 may be a trough type, a tower type, a dish type, or the like.

  FIG. 3 is a diagram showing a flow of operation of the pressure adjusting unit 42 in the steam generation process of the steam generator 1. In the pressure adjustment unit 42, the operation of FIG. 3 is always performed while the steam generator 1 is driven. Hereinafter, the operation of the pressure adjusting unit 42 in the steam generation process will be described.

  In the steam generation process, water is continuously circulated along the circulation path 33 by driving the pump 32. As described above, the water passing through the solar light collecting device 2 is heated by the condensed sunlight and then returned to the gas-liquid drum 31. Further, in the pressure sensor 422 of the pressure adjusting unit 42, the measurement value of the internal pressure of the gas-liquid drum 31 is repeatedly acquired at predetermined time intervals during the steam generation process.

  For example, immediately after the driving of the steam generator 1 is started at the same time as sunrise, the internal pressure (measured value) of the gas-liquid drum 31 is less than a predetermined set pressure (for example, 1.0 MPa (megapascal)). Is confirmed (step S11), and the pressure control valve 421 is closed (step S12). When the pressure control valve 421 is already closed, the closed state is maintained. Here, the set pressure is a pressure set to use steam in the external equipment 9, and when the internal pressure of the gas-liquid drum 31 is less than the set pressure, the gas-liquid drum 31 to the external equipment 9 Steam is not supplied. In the external facility 9, a necessary amount of steam is generated using the auxiliary boiler 91. As a result, the external equipment 9 can be operated while the steam supply flow rate from the steam generator 1 is zero. The steam supply path 41 is provided with a check valve (not shown), and the steam from the auxiliary boiler 91 does not flow back through the steam supply path 41.

  In the steam generator 1, the temperature of the water circulating in the circulation path 33 is gradually increased by the heating by the solar light collector 2, and the internal pressure of the gas-liquid drum 31 is also increased. When the internal pressure becomes equal to or higher than the set pressure (step S11), it is subsequently confirmed that the internal pressure is less than a predetermined upper limit pressure (eg, 2.2 MPa) higher than the set pressure (step S13). Details of the upper limit pressure will be described later. Further, when it is confirmed that the opening degree of the pressure control valve 421 is equal to or less than a predetermined set opening degree (step S14), the pressure control valve 421 is set to the set opening degree (step S15). Here, since the opening degree of the pressure control valve 421 is 0% (closed state) and the set opening degree is larger than 0% as will be described later, the pressure control valve 421 is slowly opened to become the set opening degree. . When the pressure control valve 421 is already at the set opening, the set opening is maintained.

  The set opening degree of the pressure control valve 421 is an arbitrary opening degree that is larger than 0% and sufficiently smaller than 100%. The set opening is preferably an opening of 50% or less, and more preferably the minimum adjustable opening. The pressure control valve 421 having the set opening can be regarded as a throttle portion in which the flow passage area is partially reduced in the steam supply passage 41. When the pressure control valve 421 is at the set opening, the steam (saturated steam) in the gas-liquid drum 31 is supplied to the external equipment 9 through the steam supply path 41 at a relatively small supply flow rate. In the external facility 9, the auxiliary boiler 91 is used to replenish the steam that is insufficient in the external facility 9. Further, since the flow rate of the steam flowing through the steam supply path 41 is greatly limited, the internal pressure of the gas-liquid drum 31 varies depending on the amount of solar radiation (direct solar radiation amount).

  When the internal pressure of the gas-liquid drum 31 becomes equal to or higher than the upper limit pressure (steps S11 and S13), the pressure adjusting unit 42 adjusts the opening degree of the pressure control valve 421 so that the internal pressure is maintained at approximately the upper limit pressure. That is, constant pressure control of the internal pressure is performed (step S16). In the constant pressure control, the area of the flow path through which the steam passes in the steam supply path 41 is adjusted based on the measurement value of the pressure sensor 422. For example, when the internal pressure is somewhat higher than the upper limit pressure, the opening degree of the pressure control valve 421 is slowly increased. In the constant pressure control, the opening degree of the pressure control valve 421 is adjusted within a range not less than the set opening degree.

  Here, the upper limit pressure is, for example, the maximum use pressure defined as the specification of the gas-liquid drum 31 or a pressure slightly lower than the maximum use pressure. Therefore, the gas-liquid drum 31 is not damaged by controlling the gas-liquid drum 31 to approximately the upper limit pressure. When the internal pressure of the gas-liquid drum 31 reaches the upper limit pressure, heat storage of an amount corresponding to the difference between the upper limit pressure and the set pressure in the gas-liquid drum 31 is substantially completed. In the steam generator 1, the steam supply flow rate to the external equipment 9 gradually increases as the opening degree of the pressure control valve 421 increases. At this time, when a constant amount of steam is used in the external equipment 9, the amount of steam generated by the auxiliary boiler 91 is gradually reduced.

  In the constant pressure control, for example, when the internal pressure of the gas-liquid drum 31 is not less than the set pressure and less than the upper limit pressure (steps S11 and S13), the opening degree of the pressure control valve 421 is larger than the set opening degree. After confirming this (step S14), the opening degree of the pressure control valve 421 is lowered so that the internal pressure is maintained at approximately the upper limit pressure. That is, the constant pressure control of the internal pressure is performed as described above (step S16).

  For example, when sunlight is blocked by clouds or the like and the amount of solar radiation decreases, the internal pressure of the gas-liquid drum 31 continuously becomes equal to or higher than the set pressure and lower than the upper limit pressure (steps S11 and S13). Also in this case, as long as the opening degree of the pressure control valve 421 is larger than the set opening degree (step S14), as the constant pressure control of the internal pressure, the opening degree of the pressure control valve 421 is lowered within the range above the set opening degree. (Step S16). Therefore, even in a state where the amount of solar radiation is small, the internal pressure of the gas-liquid drum 31 is kept near the upper limit pressure for a while. Further, the supply of steam from the steam generator 1 to the external facility 9 is continued. Of course, as the opening degree of the pressure control valve 421 is reduced, the flow rate of the steam supplied to the external equipment 9 gradually decreases. At this time, when a certain amount of steam is used in the external equipment 9, the amount of steam generated by the auxiliary boiler 91 is gradually increased.

  When the amount of solar radiation is small, the internal pressure of the gas-liquid drum 31 gradually decreases from the vicinity of the upper limit pressure toward the set pressure (steps S11 and S13). When the opening of the pressure control valve 421 is lowered to the set opening as the constant pressure control (step S14), the pressure control valve 421 is maintained at the set opening (step S15). As the amount of solar radiation is further reduced, the internal pressure of the gas-liquid drum 31 gradually decreases to near the set pressure. In the pressure adjusting unit 42, since the pressure control valve 421 is maintained at the set opening degree even during this period, the supply of steam to the external equipment 9 is continued although the supply flow rate is relatively small.

  When the internal pressure becomes less than the set pressure (step S11), the pressure control valve 421 is slowly closed and closed (step S12). Thereby, the supply flow rate of the steam from the steam generator 1 to the external facility 9 becomes zero. In the steam generator 1, when the internal pressure of the gas-liquid drum 31 has reached the upper limit pressure (that is, when water at a temperature corresponding to the upper limit pressure is stored in the gas-liquid drum 31), the amount of solar radiation is Even when there is almost no state, the supply of steam can be continued, for example, for about 10 minutes by heat storage in the gas-liquid drum 31. Therefore, by gradually increasing the output of the auxiliary boiler 91 during this period, it is possible to secure a necessary amount of steam in the external equipment 9 when the steam supply flow rate becomes zero. In the steam generator 1, when the amount of solar radiation disappears due to sunset, the driving of the pump 32 is stopped, and the steam generation process ends.

In an example of the steam generator 1, the capacity of the gas-liquid drum 31 is 2.5 m ³ , the supply pressure to the external equipment 9 is 0.8 MPa (absolute pressure, the same applies hereinafter), and the gas-liquid drum 31 in step S11 It is assumed that the set pressure is 1.1 MPa and the upper limit pressure of the gas-liquid drum 31 in step S13 is 2.3 MPa. When the opening degree of the pressure control valve 421 is 100%, the Cv value is 5, and when the internal pressure of the gas-liquid drum 31 is 2.3 MPa, the steam supply flow rate is 1.3 ton / h (1.3 hour / hour). Tons). The range ability of the pressure control valve 421 is 30: 1. The set opening degree of the pressure control valve 421 in step S15 is 30%. At this time, the Cv value becomes 0.5 due to the equal percentage characteristic. When the opening degree of the pressure control valve 421 is 30%, when the internal pressure is 1.1 MPa, the steam supply flow rate is 50 kg / h, and when the internal pressure is 2.3 MPa, the steam supply flow rate is 110 kg / h. As described above, when the internal pressure becomes 2.3 MPa or more, the opening degree of the pressure control valve 421 increases by the constant pressure control in step S16. When the gas-liquid drum 31 itself is regarded as a steam accumulator, 65 kg / m ³ of steam is generated at an initial pressure of 2.3 MPa and a final pressure of 1.1 MPa, so that a heat storage amount of 163 kg (= 65 × 2.5) is obtained. Even at a supply flow rate of / h, the steam supply can be continued for about 10 minutes.

  As described above, in the pressure adjusting unit 42 of the steam generator 1, when the internal pressure of the gas-liquid drum 31 is less than the set pressure, the passage of steam through the steam supply path 41 is blocked. On the other hand, when the internal pressure is equal to or higher than the set pressure, the steam is passed through the constricted portion in which the flow passage area is partially reduced in the steam supply path 41, thereby supplying the steam to the external equipment 9 Vary the pressure. Thereby, in the steam generator 1, the steam is supplied to the external equipment 9 when the amount of solar radiation is large, and the internal pressure of the gas-liquid drum 31 is made higher than the set pressure in a short time to substantially store heat. Is possible. Further, even when the amount of solar radiation is small, steam can be continuously supplied to the external equipment 9 for a certain period. As a result, in the steam generator 1, with a simple structure, a rapid change (mainly a decrease) in the steam supply flow rate due to a change in the amount of solar radiation is prevented, that is, the steam supply flow rate to the external equipment 9 is gently changed. Can be made.

  Further, when the internal pressure of the gas-liquid drum 31 is equal to or higher than the upper limit pressure, the internal pressure is maintained at approximately the upper limit pressure by the pressure adjusting unit 42. Thereby, when there is a sufficient amount of solar radiation, it is possible to supply steam to the external equipment 9 at a relatively high supply flow rate while continuously storing excess heat in the gas-liquid drum 31. Further, when the upper limit pressure is twice or more the set pressure, the control range of the internal pressure of the gas-liquid drum 31 can be increased, and the amount of heat that can be stored in the gas-liquid drum 31 can be increased.

  As described above, in the steam generator 1, heat is stored in the gas-liquid drum 31 that is higher than the set pressure, and therefore, no steam accumulator is provided in the steam supply path 41. As described above, the gas-liquid drum 31 also functions as a steam accumulator, whereby heat can be efficiently stored with a small amount of high-temperature water while simplifying the configuration of the steam generator 1. Depending on the design of the steam generator 1, a steam accumulator may be provided in the steam supply path 41 as an auxiliary.

  By the way, although the external boiler 9 is provided with an auxiliary boiler 91 that generates steam with fuel, it is difficult for the auxiliary boiler 91 to change the amount of generated steam rapidly. However, in the steam generator 1, the steam supply flow rate to the external equipment 9 can be gradually changed as described above. Therefore, in the external equipment 9, a certain amount of steam is generated by the steam generator 1 and the auxiliary boiler 91. Can be used stably.

  The steam generator 1 can be variously modified.

  In the above-described embodiment, the pressure control valve 421 adjusted to the set opening functions as a throttle unit in the steam supply path 41, whereby the pressure regulator 42 is realized with a simple configuration. May be realized by a configuration other than the pressure control valve 421. For example, two flow paths arranged in parallel in a part of the steam supply path 41 are provided, and a pipe member having a partially reduced flow area is provided as a throttle part in one flow path, and the upper limit is provided in the other flow path. A constant pressure valve (pressure reducing valve) for pressure is provided. The two flow paths are connected to the gas-liquid drum 31 via a switching valve, and by selectively switching the two flow paths according to the internal pressure of the gas-liquid drum 31, the steam is allowed to pass through the throttle portion. And it is implement | achieved to maintain an internal pressure at about an upper limit pressure.

  For example, when the internal pressure that can be taken in the gas-liquid drum 31 is lower than the maximum operating pressure of the gas-liquid drum 31, the constant pressure control may be omitted. That is, when the internal pressure of the gas-liquid drum 31 is less than the set pressure, the passage of the steam through the steam supply path 41 is blocked, and when the internal pressure is equal to or higher than the set pressure, the steam in the throttle portion of the steam supply path 41 Only the control of changing the internal pressure by passing the pressure may be performed in the pressure adjusting unit 42.

  In the above embodiment, water is stored in the gas-liquid drum 31, but other fluids such as ammonia may be stored in the gas-liquid drum 31, for example.

  The steam generator 1 using sunlight can be used for various purposes such as salt production and sake brewing in addition to seawater desalination (fresh water). The steam generator 1 can be added to various facilities having a boiler, and thereby the fuel consumed in the boiler (auxiliary boiler) can be reduced. Of course, the steam generator 1 may be used for power generation.

  The configurations in the above-described embodiments and modifications may be combined as appropriate as long as they do not contradict each other.

DESCRIPTION OF SYMBOLS 1 Steam generator 2 Sunlight condensing device 9 External equipment 31 Gas-liquid drum 32 Pump 41 Steam supply path 42 Pressure adjustment part 91 Auxiliary boiler 421 Pressure control valve

Claims (6)

A steam generator using sunlight,
A solar concentrator that heats the fluid with the concentrated sunlight;
A gas-liquid drum for storing the vapor and liquid of the fluid;
A pump for continuously circulating the fluid between the solar light collecting device and the gas-liquid drum;
A steam supply path connecting the gas-liquid drum and external equipment;
When the internal pressure of the gas-liquid drum is less than a set pressure set for using the steam in the external equipment, the steam is blocked from passing through the steam supply path, and the internal pressure is When the pressure is equal to or higher than a set pressure, the internal pressure is changed while supplying the steam to the external equipment by passing the steam through a constricted portion in which the flow area is partially reduced in the steam supply path. A pressure adjustment unit;
A steam generator characterized by comprising: The steam generator according to claim 1,
When the internal pressure is equal to or higher than the upper limit pressure higher than the set pressure, the pressure adjusting unit adjusts the area of the flow path through which the steam passes in the steam supply path, so that the internal pressure is approximately A steam generator characterized by maintaining an upper limit pressure. The steam generator according to claim 2,
The pressure adjusting unit includes a pressure control valve provided in the steam supply path;
When the internal pressure is equal to or higher than the upper limit pressure, the opening of the pressure control valve is adjusted,
The steam generator, wherein the pressure control valve functions as the throttle portion when the internal pressure is equal to or higher than the set pressure and lower than the upper limit pressure. The steam generator according to any one of claims 1 to 3,
The steam generating device, wherein the upper limit pressure is twice or more the set pressure. The steam generator according to any one of claims 1 to 4,
The steam generator is characterized in that no steam accumulator is provided in the steam supply path. The steam generator according to any one of claims 1 to 5,
In the external equipment, an auxiliary boiler for generating steam with fuel is provided.

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