JP7294187B2 - fuel cell system - Google Patents

Description

The present invention relates to fuel cell systems.

The fuel cell system described in Patent Document 1 includes a reformer that reforms a raw material gas by a steam reforming reaction to generate a fuel gas to be supplied to the fuel cell, and an unreacted fuel gas that is discharged from the fuel cell. and a heat exchanger for condensing water vapor contained in the combustion exhaust gas to recover water. In this fuel cell system, if the supply of steam to the reformer is not self-sustaining, in which only the water collected in the fuel cell system is established, the amount of raw material gas supplied is increased, and the flue gas is to increase the dew point of As a result, by increasing the dew point of the combustion exhaust gas, the amount of water recovered by the heat exchanger is increased, and water independence is promoted.

JP 2016-225103 A

However, increasing the supply of raw material gas not for the power output of the fuel cell but for establishing water independence will increase the ratio of the raw material gas supply to the amount of power generation, and the power generation efficiency will be greatly improved. Getting worse.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a fuel cell system that can achieve water independence without significantly increasing the amount of source gas supplied.

In order to achieve the above object, in the invention according to claim 1,
The fuel cell system
a fuel cell (2) that generates electricity through an electrochemical reaction using a fuel gas and an oxidant gas;
a fuel supply channel (3) for supplying fuel gas to the fuel cell;
a raw material pump (12) provided in the fuel supply channel for sucking and discharging a raw material gas that is reformed to become a fuel gas;
an ejector (13) provided downstream of the raw material pump in the fuel supply channel and having a nozzle portion (13a), a suction portion (13b) and a discharge portion (13c);
a reformer (14) provided in the fuel supply channel downstream of the ejector discharge portion and configured to reform the raw material gas by a steam reforming reaction to generate the fuel gas;
a recycling flow path (10) for returning part of the fuel off-gas containing unreacted fuel gas discharged from the fuel cell to the suction part of the ejector as recycled gas;
an assist channel (11) for returning part of the fuel gas that has flowed out of the reformer to the upstream side of the raw material pump in the fuel supply channel as assist gas;
an assist adjustment unit (20) provided in the assist flow path for adjusting the flow rate of the assist gas;
a steam supply channel (4) connected between the raw material pump and the ejector in the fuel supply channel for supplying steam to the reformer;
a water tank (15) connected to the steam supply channel and storing liquid water;
a water evaporator (17) provided in the steam supply channel for evaporating liquid water sent from the water tank to generate steam;
a water recovery device (19, 25) for recovering water contained in at least one of the combustion exhaust gas and the assist gas generated by burning the fuel off-gas and supplying the recovered water to the water tank;
a determination unit (S1) that determines whether or not water independence is established;
A flow control unit ( S4) and.

According to this, by increasing the flow rate of the assist gas when water independence is not established, the flow rate of the driving flow ejected from the nozzle portion of the ejector can be achieved without significantly increasing the supply amount of the source gas. can be increased. As a result, the suction force of the ejector is increased, and the flow rate of the recycle gas can be increased. The recycled gas includes power-generated water generated by power generation of the fuel cell. As the flow rate of the recycled gas increases, the amount of water generated by power generation supplied to the reformer increases, so the amount of water flowing out from the water tank to the water evaporator can be reduced. As a result, water self-reliance can be established without significantly increasing the supply amount of the raw material gas.

It should be noted that the reference numerals in parentheses attached to each component etc. indicate an example of the correspondence relationship between the component etc. and specific components etc. described in the embodiments described later.

1 is a schematic diagram showing the overall configuration of a fuel cell system in a first embodiment; FIG. 4 is a flowchart showing control processing executed by the control device in the first embodiment; FIG. 16 is a flow chart showing control processing executed by a control device in a sixth embodiment; FIG. FIG. 11 is a schematic diagram showing the overall configuration of a fuel cell system in a seventh embodiment;

An embodiment of the present invention will be described below with reference to the drawings. In addition, in each of the following embodiments, portions that are the same or equivalent to each other will be described with the same reference numerals.

(First embodiment)
As shown in FIG. 1, the fuel cell system 1 includes a fuel cell 2, a fuel supply channel 3, a water vapor supply channel 4, an air supply channel 5, a fuel offgas channel 6, and an air offgas channel. 7 , a combustor 8 , a flue gas flow path 9 , a recycling flow path 10 and an assist flow path 11 .

The fuel cell 2 generates electricity through an electrochemical reaction using fuel gas and oxidant gas. In this embodiment, the fuel cell 2 is a solid oxide fuel cell (SOFC) and is an assembly of a plurality of cells. In one cell, a fuel electrode (that is, anode) is formed on one side of the electrolyte, and an oxidant electrode (that is, cathode) is formed on the other side. As the fuel gas, a gas containing hydrogen gas produced by a steam reforming reaction in the reformer 14, which will be described later, is used. Air is used as the oxidant gas. Electrical energy is generated by an electrochemical reaction between hydrogen in the fuel gas and oxygen in the oxidant gas.

The fuel supply channel 3 is a channel for supplying fuel gas to the fuel electrode of the fuel cell 2 . The fuel supply channel 3 is connected to the fuel inlet side of the fuel cell 2 . A raw material pump 12 , an ejector 13 and a reformer 14 are provided in the fuel supply channel 3 .

The raw material pump 12 is provided upstream of the fuel supply passage 3 . The raw material pump 12 sucks and discharges gas such as raw material gas. The raw material pump 12 has its discharge capacity adjusted by changing the rotational speed. The raw material gas is reformed in the reformer 14 to become the fuel gas for the fuel cell 2 . In this embodiment, city gas is used as the source gas. Town gas is gas containing hydrocarbons. Gases containing hydrocarbons other than city gas may be used as the raw material gas.

The ejector 13 is provided downstream of the raw material pump 12 and upstream of the reformer 14 in the fuel supply passage 3 . The ejector 13 has a nozzle portion 13a, a suction portion 13b, and a discharge portion 13c. The nozzle part 13a injects the gas sent from the raw material pump 12 as a driving flow. The suction part 13b sucks the gas flowing through the flow path connected to the suction part 13b by the driving flow ejected from the nozzle part 13a as a suction flow. The ejection part 13c ejects a mixed flow of the driving flow and the suction flow.

The nozzle portion 13 a is connected to the upstream side of the fuel supply passage 3 . The discharge portion 13c is connected to the downstream side of the fuel supply channel 3. As shown in FIG. The suction portion 13b is connected to the recycling channel 10. As shown in FIG.

The reformer 14 is provided downstream of the discharge portion 13 c of the ejector 13 in the fuel supply passage 3 . The reformer 14 is supplied with a mixed gas of raw material gas and water vapor. Further, in the reformer 14 , the mixed gas is heated by heat exchange with the flue gas flowing through the flue gas passage 9 . The reformer 14 reforms the raw material gas by a steam reforming reaction using steam to generate a fuel gas containing hydrogen gas.

The steam supply channel 4 is a channel for supplying steam to the reformer 14 . One end of the steam supply channel 4 is connected between the raw material pump 12 and the nozzle portion 13 a of the ejector 13 in the fuel supply channel 3 . The other end of the steam supply channel 4 is connected to the water tank 15 . A water pump 16 and a water evaporator 17 are provided in the steam supply channel 4 .

The water tank 15 stores liquid water. The water pump 16 sucks and discharges liquid water to send the liquid water from the water tank 15 to the water evaporator 17 . The water evaporator 17 evaporates water by heat exchange with the flue gas flowing through the flue gas passage 9 to generate steam.

The air supply channel 5 is a channel for supplying air to the oxidant electrode of the fuel cell 2 . The air supply channel 5 is connected to the air inlet side of the fuel cell 2 . An air preheater 18 is provided in the air supply channel 5 . The air preheater 18 heats the air by heat exchange with the flue gas flowing through the flue gas passage 9 . Air preheater 18 supplies preheated air to fuel cell 2 .

The fuel off-gas channel 6 is a channel through which the fuel off-gas flows. The fuel off-gas is gas containing unreacted fuel gas discharged from the fuel cell 2 . The upstream side of the fuel offgas channel 6 is connected to the fuel outlet side of the fuel cell 2 .

The air off-gas channel 7 is a channel through which the air off-gas flows. The air off-gas is gas containing unreacted air discharged from the fuel cell 2, and is also called oxidant off-gas. The upstream side of the air offgas channel 7 is connected to the air outlet side of the fuel cell 2 .

The combustor 8 is connected to the downstream side of the fuel offgas flow path 6 and the downstream side of the air offgas flow path. The combustor 8 burns the fuel gas contained in the fuel off-gas and the oxidant gas contained in the oxidant off-gas to generate flue gas.

The upstream side of the flue gas flow path 9 is connected to the outlet side of the combustor 8 . The flue gas channel 9 is a channel through which the flue gas flows. The flue gas flow path 9 is arranged to pass through each of the reformer 14 , the air preheater 18 and the water evaporator 17 . In this embodiment, the flue gas passage 9 is arranged so that the flue gas flows through the reformer 14 , the air preheater 18 and the water evaporator 17 in this order. A water collector 19 is provided downstream of the water evaporator 17 in the flue gas flow path 9 .

The water recovery device 19 is a water recovery device for flue gas that recovers water contained in flue gas. In the water collector 19, the flue gas is cooled by heat exchange between the flue gas and the heat exchange medium. By cooling the flue gas, water vapor contained in the flue gas is condensed and liquid water is recovered. The liquid water recovered by the water recovery device 19 is supplied to the water tank 15 . The water recovery device 19 is also an exhaust heat recovery device that recovers exhaust heat from combustion exhaust gas. In the water recovery device 19, the heat exchange medium is heated by heat exchange between the flue gas and the heat exchange medium. Thereby, exhaust heat of combustion exhaust gas is recovered.

The recycle flow path 10 is a flow path that returns part of the fuel off-gas to the suction portion 13b of the ejector 13 as recycled gas. One end 10 a of the recycle channel 10 is connected to the middle of the fuel offgas channel 6 . The other end 10 b of the recycling channel 10 is connected to the suction portion 13 b of the ejector 13 .

The assist flow path 11 is a flow path that returns part of the fuel gas that has flowed out of the reformer 14 to the upstream side of the raw material pump 12 in the fuel supply flow path 3 as assist gas. One end 11 a of the assist channel 11 is connected to the downstream side of the reformer 14 in the fuel supply channel 3 . The other end 11 b of the assist channel 11 is connected to the upstream side of the raw material pump 12 in the fuel supply channel 3 .

An assist adjustment valve 20 is provided in the assist flow path 11 . The assist adjustment valve 20 is an assist adjustment section that adjusts the flow rate of the assist gas flowing through the assist flow path 11 . The assist adjustment valve 20 adjusts the flow rate of the assist gas by changing the valve opening degree. The assist regulating valve 20 can close the assist flow path 11 .

The fuel cell system 1 has a control device 21 . The control device 21 controls the operations of the raw material pump 12, the water pump 16, the assist adjustment valve 20, and the like. A water level sensor 22 and a flow meter 23 are connected to the input side of the control device 21 . The water level sensor 22 is provided in the water tank 15 and detects the water level inside the water tank 15 . A flow meter 23 is provided in the recycle flow path 10 and measures the flow rate of the recycle gas.

The fuel cell system 1 also includes a current regulator 24 that regulates the sweep current of the fuel cell 2 . A current regulator 24 regulates the power output of the fuel cell 2 . Current regulator 24 is controlled by controller 21 . Electric power generated by the fuel cell 2 is supplied to the load via the current regulator 24 .

Next, operation of the fuel cell system 1 will be described. The operation of the raw material pump 12 causes the raw material gas to flow through the fuel supply channel 3 . By the operation of the water pump 16, water is supplied from the water tank 15 to the water evaporator 17, and the water vapor generated by the water evaporator 17 flows into the fuel supply passage 3 and mixes with the raw material gas to form a mixed gas. . The mixed gas is supplied to the reformer 14 via the ejector 13 . The reformer 14 reforms the raw material gas to generate fuel gas. The generated fuel gas flows out of the reformer 14 and into the fuel cell 2 . Also, air is supplied to the fuel cell 2 from the air supply channel 5 . Thereby, the fuel cell 2 generates electric power.

A part of the fuel off-gas discharged from the fuel cell 2 flows through the recycling channel 10 as a recycled gas, is sucked from the suction portion 13b of the ejector 13, and is supplied to the fuel cell 2. FIG. As a result, part of the fuel off-gas is reused for power generation by the fuel cell 2 .

Another portion of the fuel off-gas is supplied to combustor 8 . Air off-gas discharged from the fuel cell 2 is supplied to the combustor 8 . The fuel off-gas and air off-gas are combusted in combustor 8 to produce flue gas. The generated flue gas flows through the flue gas passage 9 .

Since the assist adjustment valve 20 is open when the raw material pump 12 is in operation, part of the fuel gas that has flowed out of the reformer 14 flows through the assist flow path 11 as assist gas. As a result, compared with the case where the fuel cell system 1 does not include the assist flow path 11 under the same flow rate conditions of the raw material gas and steam, the driving flow flowing into the nozzle portion 13a increases and is sucked into the suction portion 13b. The flow rate of recycled gas is increased. As described above, even if the flow rate of the raw material gas and the flow rate of the steam are not increased above the flow rates necessary for power generation, the flow rate of the driving flow can be increased by flowing the assist gas through the assist flow path 11, and the ejector 13 can increase the capacity of Power generation efficiency can be improved by increasing the flow rate of the recycled gas.

At this time, the control device 21 instructs the current adjusting device 24 about the magnitude of the sweep current of the fuel cell 2, and the necessary raw material gas is determined according to the magnitude of the sweep current adjusted by the current adjusting device 24. The operation of the raw material pump 12 and the like is controlled so that the raw material is supplied to the fuel cell 2 .

2, the control device 21 controls the raw material pump 12, the assist adjustment valve 20, and the water pump 16 so that the water independence is established when the water independence is not established. . The processing shown in FIG. 2 is repeatedly executed at a predetermined cycle. Also, the steps shown in the figure correspond to functional units that implement various functions. This also applies to other drawings.

Water independence is a state in which water supply to the water tank 15 from the outside of the fuel cell system 1 is not required. More specifically, water independence means a state in which the amount of water flowing into the water tank 15 from the water collector 19 is greater than the amount of water flowing out of the water tank 15 to the water evaporator 17, or The amount of water in the water tank 15 is greater than the predetermined amount of water. If the amount of water flowing into the water tank 15 is larger than the amount of water flowing out, the water can be supplied from the water tank 15 to the water evaporator 17 without supplying water to the water tank 15 from the outside of the fuel cell system 1. can be supplied. Further, if the amount of water in the water tank 15 is greater than the predetermined amount of water, as long as this state is maintained, water is supplied from the water tank 15 without replenishing water from the outside of the fuel cell system 1 to the water tank 15 . A supply of water to the evaporator 17 is possible.

In step S1, the control device 21 determines whether the water level of the water tank 15 detected by the water level sensor 22 is higher than the determination water level. Thereby, the control device 21 determines whether or not the amount of water in the water tank 15 is greater than the predetermined amount of water. That is, the control device 21 determines whether or not water independence is established. When the water level of the water tank 15 is higher than the judgment water level, the control device 21 makes a YES judgment and proceeds to step S2. When the water level of the water tank 15 is lower than the judgment water level, the controller 21 makes a NO judgment and proceeds to step S3.

In step S2, the controller 21 sets the target value A of the recycle gas circulation rate to a predetermined value X [%]. The predetermined value X is determined according to the magnitude of the sweep current of the fuel cell 2 . After that, the controller 21 proceeds to step S4.

On the other hand, in step S3, the controller 21 sets the target value A of the recycle gas circulation rate to a value higher than the current value (that is, the current value+Y [%]). For the first time, the predetermined value X is used as the current value. After that, the controller 21 proceeds to step S4.

In step S4, the control device 21 controls the raw material pump 12, the assist adjustment valve 20, and the water pump 16 so that the flow rate of the raw material gas becomes the target value and the circulation rate of the recycled gas becomes the target value A. The target value of the raw material gas flow rate is determined according to the magnitude of the sweep current of the fuel cell 2 .

Subsequently, in step S5, the controller 21 measures the circulation rate of the recycled gas. The circulation rate of the recycled gas is the ratio of the flow rate of the recycled gas to the flow rate of the fuel off-gas discharged from the fuel cell 2 . The fuel off-gas flow rate is calculated using the source gas flow rate and the water flow rate supplied to the water evaporator 17 . The flow rate of the raw material gas is measured by a flow meter (not shown) installed upstream of the junction of the assist channel 11 (that is, the other end 11b of the assist channel 11) in the fuel supply channel 3. value is used. A calculated value calculated from the rotation speed of the water pump 16 is used as the flow rate of water supplied to the water evaporator 17 . A measured value measured by the flow meter 23 is used as the flow rate of the recycled gas.

Thus, in the present embodiment, the control device 21 uses the measured value of the flow meter 23 provided in the recycling flow path 10 as the flow rate of the recycled gas to calculate the circulation rate of the recycled gas. Note that the flow rate of the fuel off-gas may be obtained by a method other than the above.

Subsequently, in step S6, the control device 21 determines whether or not the current value of the circulation rate measured in step S5 is equal to or greater than the target value A. If the current value of the circulation rate is not equal to or greater than the target value A, the controller 21 makes a NO determination and returns to step S4. When the current value of the circulation rate is equal to or greater than the target value A, the control device 21 makes a YES determination, and once terminates the flow shown in FIG.

According to this embodiment, when the water level of the water tank 15 is higher than the determination water level, the control device 21 makes a YES determination in step S1, and performs steps S2, S4, S5, and S6. As a result, the circulation rate of the recycled gas becomes the target value A set in step S2.

When the water level of the water tank 15 is lower than the judgment water level, the control device 21 makes a NO judgment in step S1, and increases the target value A of the recycle gas circulation rate in step S3. In step S4, the control device 21 increases the rotation speed of the raw material pump 12 and increases the opening degree of the assist adjustment valve 20 so that the circulation rate of the recycled gas reaches the target value A. reduce the number of revolutions. That is, the control device 21 controls the raw material pump 12 to increase the discharge capacity, controls the assist adjustment valve 20 to increase the flow rate of the assist gas, and further controls the water pump to decrease the discharge capacity. 16. As a result, the flow rate of the assist gas increases while the flow rate of the raw material gas flowing into the raw material pump 12 remains substantially constant. The flow rate of water supplied to the water evaporator 17 is reduced.

According to this, by increasing the flow rate of the assist gas when the water level in the water tank 15 becomes lower than the judgment water level, the driving flow of the ejector 13 can be increased without significantly increasing the supply amount of the raw material gas. can be increased. As a result, the suction force of the ejector 13 is increased, and the flow rate of the recycle gas can be increased. The recycled gas includes power-generated water, which is water generated by the power generation of the fuel cell 2 . As the flow rate of the recycled gas increases, the water generated by power generation supplied to the reformer 14 increases, so the amount of water flowing out from the water tank 15 to the water evaporator 17 can be reduced. As a result, the amount of water flowing into the water tank 15 is larger than the amount of water flowing out of the water tank 15, so that the water level of the water tank 15 can be raised to be higher than the judgment water level. Therefore, according to this, the water independence can be established without greatly increasing the supply amount of the raw material gas.

In this embodiment, step S1 corresponds to a determination unit that determines whether or not water independence is established. Steps S2 and S3 correspond to a circulation rate target value setting unit that sets the target value of the circulation rate. Step S4 corresponds to the flow control section. Step S5 corresponds to a circulation rate measuring unit that measures the circulation rate.

Further, in step S4 when the water level in the water tank 15 becomes lower than the judgment water level, each control of the raw material pump 12, the assist adjustment valve 20, and the water pump 16 may be started in any order. may be initiated at the same time. However, for the following reasons, increasing the rotation speed of the raw material pump 12, increasing the opening degree of the assist adjustment valve 20, and decreasing the rotation speed of the water pump 16 are performed in this order. is desirable.

If the opening degree of the assist adjustment valve 20 is increased before the rotation speed of the raw material pump 12 is increased, the flow rate of the raw material gas decreases until the rotation speed of the raw material pump 12 is increased. If the flow rate of the raw material gas decreases and the flow rate of the raw material gas falls below the target value, the flow rate of the fuel gas required for power generation cannot be ensured, possibly causing damage to the cell. Therefore, first, the rotation speed of the raw material pump 12 is increased. As a result, the flow rate of the raw material gas increases once. Next, the opening degree of the assist adjustment valve 20 is increased. As a result, the flow rate of the raw material gas is reduced to the extent that it does not fall below the target value, and the flow rate of the assist gas is increased. As a result, the flow rate of the raw material gas can always be kept above the target amount.

Further, if the rotation speed of the water pump 16 is decreased before the rotation speed of the raw material pump 12 is increased and the opening degree of the assist adjustment valve 20 is increased, the flow rate of the driving flow of the ejector 13 is decreased. In this case, the power of the ejector 13 is reduced during the period until the rotation speed of the raw material pump 12 is increased and the opening degree of the assist adjustment valve 20 is increased, and the flow rate of the recycle gas sucked from the suction portion 13b is reduced. Circulation decreases. If the circulation rate drops, there is a possibility that the flow rate of fuel gas required for power generation cannot be secured. Therefore, it is desirable to first increase the opening of the assist adjustment valve 20 to increase the flow rate of the assist gas, and then decrease the rotation speed of the water pump 16 .

(Second embodiment)
In this embodiment, the method of measuring the circulation rate of the recycled gas performed in step S5 is different from that in the first embodiment. Other configurations of the fuel cell system 1 are the same as those of the first embodiment.

In the first embodiment, the control device 21 calculates the circulation rate of the recycled gas using the measured value of the flow meter 23 provided in the recycling channel 10 as the flow rate of the recycled gas. On the other hand, in the present embodiment, the control device 21 uses the recycle gas flow rate estimated based on the measured value of the pressure drop of the recycle gas between two distant points in the recycle flow path 10 as the recycle gas flow rate. Calculate the circulation rate of the recycle gas using the estimated value of the flow rate of

The pressure drop amount of the recycled gas is measured by a pressure drop amount measuring device provided in the recycling flow path 10 . Pressure gauges provided at two separate locations in the recycle flow path 10 can be used as measuring instruments for measuring the amount of pressure drop. Also, a differential pressure gauge may be used as a measuring device for the amount of pressure drop.

There is a certain relationship between the flow rate of the recycled gas flowing through the recycling channel 10 and the amount of pressure drop of the recycled gas flowing through the recycling channel 10 . Therefore, the flow rate of the recycled gas can be calculated using the measured pressure drop amount and the relationship between the pressure drop amount and the flow rate of the recycled gas.

The recycled gas flowing through the recycling channel 10 is at a high temperature. Therefore, when the flow rate of the recycled gas is measured by the flow meter 23, the heat resistance of the flow meter 23 becomes a problem. In contrast, a pressure gauge or a differential pressure gauge can be installed so as not to be exposed to the hot recycled gas. Therefore, such a problem does not occur.

Moreover, when the flow meter 23 is used, a high temperature flow meter is required. Pressure gauges are generally less expensive than flow meters for high temperatures. Therefore, according to this embodiment, the fuel cell system 1
cost can be reduced.

(Third embodiment)
This embodiment differs from the first and second embodiments in the method of measuring the circulation rate of the recycled gas performed in step S5. Other configurations of the fuel cell system 1 are the same as those of the first embodiment.

In this embodiment, the control device 21 uses an estimated value of the flow rate of the recycled gas, which is estimated from the measured value of the pressure drop between the inlet side and the outlet side of the reformer 14, as the flow rate of the recycled gas. , to calculate the circulation rate of the recycled gas.

The pressure drop between the inlet side and the outlet side of the reformer 14 is the pressure drop between the gas entering the reformer 14 and the gas leaving the reformer 14 . The amount of pressure drop between the inlet side and the outlet side of the reformer 14 is measured by a pressure gauge provided on the inlet side of the reformer 14 and a pressure gauge provided on the outlet side of the reformer 14. be done.

There is a certain relationship between the amount of pressure drop between the inlet side and the outlet side of the reformer 14 and the flow rate of the gas flowing out of the reformer 14 . Therefore, the flow rate of the gas flowing out of the reformer 14 can be calculated using the measured pressure drop amount and the relationship between the pressure drop amount and the flow rate of the gas flowing out of the reformer.

The gas discharged from the reformer 14 includes fuel gas produced by the steam reforming reaction, assist gas, and recycled gas. Therefore, the flow rate of the recycled gas can be calculated using the flow rate of the gas flowing out of the reformer 14, the flow rate of the fuel gas generated by the steam reforming reaction, and the flow rate of the assist gas. The flow rate of the fuel gas generated by the steam reforming reaction is calculated from the flow rate of the raw material gas and the flow rate of the steam supplied to the reformer. The flow rate of the assist gas is measured by a flow meter (not shown) provided in the assist flow path 11 . The flow rate of the assist gas may be calculated from the rotational speed of the raw material pump 12 and the opening degree of the assist adjustment valve 20 .

According to this embodiment, a pressure gauge is used for estimating the flow rate of the recycled gas. Therefore, effects similar to those of the second embodiment can be obtained. Further, in the second embodiment, when the amount of pressure drop in the recycled gas flowing through the recycling passage 10 is small, it is required to improve the accuracy of the pressure gauge for measuring the amount of pressure drop in the recycled gas. However, if the amount of pressure drop between the inlet side and the outlet side of the reformer 14 is sufficiently large compared to the amount of pressure drop in the recycle flow path, the pressure gauge does not have to be highly accurate.

(Fourth embodiment)
In this embodiment, the method of measuring the circulation rate of the recycle gas performed in step S5 is different from that in the first to third embodiments. Other configurations of the fuel cell system 1 are the same as those of the first embodiment.

In this embodiment, the control device 21 uses an estimated value of the flow rate of the recycled gas as the flow rate of the recycled gas, which is estimated based on the measured value of the pressure drop between the fuel inlet side and the fuel outlet side of the fuel cell 2. is used to calculate the circulation rate of the recycled gas.

The amount of pressure drop between the fuel inlet side and the fuel outlet side of the fuel cell 2 is the pressure drop between the fuel gas flowing into the fuel inlet of the fuel cell 2 and the fuel off-gas flowing out of the fuel outlet of the fuel cell 2. quantity. The amount of pressure drop between the fuel inlet side and the fuel outlet side of the fuel cell 2 is measured by a pressure gauge provided on the fuel inlet side of the fuel cell 2 and a pressure gauge provided on the fuel outlet side of the fuel cell 2. Measured.

There is a certain relationship between the amount of pressure drop between the fuel inlet side and the fuel outlet side of the fuel cell 2 and the flow rate of the fuel off-gas flowing out of the fuel cell 2 . Therefore, the flow rate of the fuel off-gas flowing out of the fuel cell 2 can be calculated using the measured pressure drop amount and the relationship between the pressure drop amount and the flow rate of the fuel off-gas.

The fuel gas produced by the reformer 14 and the recycled gas flow into the fuel inlet of the fuel cell 2 . Therefore, the flow rate of the recycle gas can be calculated using the flow rate of the fuel off-gas and the flow rate of the fuel gas generated in the reformer 14 . The flow rate of the fuel gas generated by the reformer 14 is calculated from the flow rate of the raw material gas and the flow rate of steam.

According to this embodiment, a pressure gauge is used for estimating the flow rate of the recycled gas. Therefore, effects similar to those of the second embodiment can be obtained. Further, in the second embodiment, when the amount of pressure drop in the recycled gas flowing through the recycling passage 10 is small, it is required to improve the accuracy of the pressure gauge for measuring the amount of pressure drop in the recycled gas. However, if the amount of pressure drop between the fuel inlet side and the fuel outlet side of the fuel cell 2 is sufficiently larger than the amount of pressure drop in the recycle channel, the pressure gauge does not have to be highly accurate.

(Fifth embodiment)
In this embodiment, the method of measuring the circulation rate of the recycled gas performed in step S5 is different from that in the first to fourth embodiments. Other configurations of the fuel cell system 1 are the same as those of the first embodiment.

In the present embodiment, the controller 21 uses the measured values of the temperature and the flow rate of the driving flow flowing into the nozzle portion 13a of the ejector 13 and the flow rate of the driving flow according to the temperature of the driving flow as the flow rate of the recycled gas. The circulation rate of the recycled gas is calculated using the estimated value of the flow rate of the recycled gas estimated based on the relationship with the flow rate of the suction flow sucked by the suction portion 13b.

Depending on the temperature of the driving flow of the ejector 13, there is a certain relationship between the flow rate of the driving flow and the flow rate of the suction flow. Therefore, the flow rate of the recycled gas can be estimated by using the measured values of the temperature and flow rate of the driving flow and a map showing the relationship between the flow rate of the driving flow and the flow rate of the suction flow according to the temperature of the driving flow. can do.

The temperature of the driving flow is measured by a thermometer such as a thermocouple. The flow rate of the driving flow is calculated using the rotation speed of the raw material pump 12 and the flow rate of the assist gas measured by the flow meter. A flow meter that measures the flow rate of the assist gas is installed for the operation of the fuel cell system 1 . According to this embodiment, it is sufficient to add a thermometer as a measuring instrument for measuring the flow rate of the recycled gas, and installation of a pressure gauge is unnecessary. Thermometers, such as thermocouples, are generally less expensive than pressure gauges. Therefore, an increase in cost of the fuel cell system 1 can be suppressed.

(Sixth embodiment)
As shown in FIG. 3, in the control processing performed by the control device 21 in the present embodiment, steps S7, S8, and S9 are added to the control processing in FIG. 2 performed by the control device 21 in the first embodiment. .

In step S6, when the current value of the circulation rate is not equal to or greater than the target value A, the controller 21 makes a NO determination and proceeds to step S7.

In step S7, the controller 21 determines whether or not the rotation speed of the raw material pump 12 is lower than max (that is, the maximum value). If the rotation speed of the raw material pump 12 is lower than the maximum value, the controller 21 makes a YES determination and proceeds to step S8.

In step S8, the control device 21 determines whether or not the valve opening degree of the assist adjustment valve 20 is smaller than the full opening. When the valve opening degree is smaller than the full open, the controller 21 makes a YES determination and returns to step S4.

In step S7, when the rotation speed of the raw material pump 12 is the maximum value, the control device 21 makes a NO determination and proceeds to step S9. Further, in step S8, when the valve opening degree of the assist adjustment valve 20 is fully open, the control device 21 makes a NO determination and proceeds to step S9.

In step S9, the control device 21 controls the current adjusting device 24 so that the sweep current of the fuel cell 2 becomes a value lower than the current value (that is, current value -Z [A]). After that, the control device 21 returns to step S4.

According to this, when the water level of the water tank 15 is lower than the judgment water level, the control device 21 raises the target value A of the recycle gas circulation rate in step S3. In step S4, the control device 21 increases the rotation speed of the raw material pump 12 and increases the opening degree of the assist adjustment valve 20 so that the circulation rate becomes the target value A.

In this step S4, the rotation speed of the raw material pump 12 and the opening degree of the assist adjustment valve 20 are changed to the target value A by a predetermined amount of change. Therefore, if the current value of the circulation rate is not equal to or greater than the target value A after executing step S4, the rotation speed of the raw material pump 12 is not the maximum value, and the opening of the assist adjustment valve 20 is not fully open, the circulation rate reaches the target value, the control device 21 repeats step S4. Then, when the current value of the circulation rate becomes equal to or greater than the target value A, the processing shown in FIG. 3 is once terminated.

Also, after step S4 is executed, the current value of the circulation rate does not reach the target value A, and the rotation speed of the raw material pump 12 reaches the maximum value, or the opening of the assist adjustment valve 20 is fully opened. There is In this case, the circulation rate cannot be increased any more, and the circulation rate cannot be increased to the target value A or higher. As a result, water independence cannot be established.

Therefore, when the rotation speed of the raw material pump 12 reaches the maximum value after step S4 is executed, the control device 21 makes a NO determination in step S7, executes step S9, and instructs the current adjustment device 24 to It instructs to lower the sweep current of the battery 2.

Similarly, when the opening degree of the assist regulating valve 20 is fully opened after step S4 is executed, the controller 21 makes a NO determination in step S8, executes step S9, and controls the current regulating device 24 to An instruction is given to lower the sweep current of the fuel cell 2 .

In step S4 after step S9, the controller 21 sets the flow rate of the raw material gas and the flow rate of water to target values corresponding to the magnitude of the sweep current instructed in step S9, and sets the circulation rate to the target value. The raw material pump 12, the assist adjustment valve 20, and the water pump 16 are controlled so that For example, the control device 21 reduces the rotation speed of the raw material pump 12 or reduces both the rotation speed of the raw material pump 12 and the opening degree of the assist adjustment valve 20 . This reduces the flow rate of the source gas to be supplied. Furthermore, the rotation speed of the raw material pump 12, the opening degree of the assist adjustment valve 20, and the rotation speed of the water pump 16 are adjusted so that the circulation rate becomes the target value A while the flow rate of the raw material gas is reduced.

Until the circulation rate reaches the target value A, the control device 21 repeats steps S4 to S9. When the current value of the circulation rate becomes equal to or greater than the target value A, the processing shown in FIG. 3 is once terminated.

As described above, according to the present embodiment, it is determined in step S1 that water independence is not established. Through steps S3 and S4, the discharge capacity of the raw material pump 12 is increased, and the flow rate of the assist gas is increased by the assist adjustment valve 20. FIG. After that, when the discharge capacity of the raw material pump 12 reaches the maximum, or when the flow rate of the assist gas adjusted by the assist adjustment valve 20 reaches the maximum, the controller 21 sweeps the fuel cell 2 in step S9. The current adjusting device 24 is controlled so as to decrease the current, and in step S4, the supply amount of the raw material gas becomes the flow rate corresponding to the sweep current reduced in step S9, and the circulation rate of the recycled gas reaches the target value. Thus, the raw material pump 12 and the assist regulating valve 20 are controlled.

Thus, when the raw material pump 12 reaches its maximum discharge capacity, the sweep current is made lower than the current value. As a result, the flow rate of fuel gas required for power generation can be reduced. That is, it is possible to reduce the respective flow rates of the raw material gas and water required for power generation. As a result, the circulation rate can be set to the target value, and water independence can be established. Note that in the present embodiment, step S9 corresponds to the current control section that controls the current adjusting device.

The control process of the control device 21 in this embodiment is effective when the water independence is established under the condition that the output of the fuel cell 2 is low.

(Seventh embodiment)
As shown in FIG. 4, the fuel cell system 1 of this embodiment includes a water recovery device 25 for assist gas in addition to a water recovery device 19 for fuel exhaust gas. The assist gas water recovery device 25 is provided in the assist flow path 11 and recovers water contained in the assist gas. The assist gas water recovery device 25 cools the assist gas to condense water vapor contained in the assist gas, recovers liquid water, and supplies the recovered liquid water to the water tank 15 .

In this embodiment, the fuel exhaust gas water recovery device 19 and the assist gas water recovery device 25 correspond to water recovery devices for recovering water contained in the gas. Water independence in this embodiment means that the inflow amount of water flowing into the water tank 15 from both the water recovery device 19 for the fuel exhaust gas and the water recovery device 25 for the assist gas is The amount of water flowing out to the water evaporator 17 is larger than the amount of water flowing out, or the amount of water in the water tank 15 is larger than a predetermined amount of water.

Other configurations of the fuel cell system 1 are the same as those of the first embodiment. Therefore, this embodiment can also provide the same effects as those of the first embodiment.

Furthermore, according to the present embodiment, the fuel cell system 1 supplies the water tank 15 with water recovered by both the fuel exhaust gas water recovery device 19 and the assist gas water recovery device 25 . Therefore, compared to the case where the fuel cell system 1 includes only the water recovery device 19 for fuel exhaust gas as a water recovery device, the amount of water supplied to the water tank 15 can be increased, making it easier to establish water independence. be able to.

Note that the fuel cell system 1 may include only the water recovery device 25 for the assist gas out of the water recovery device 19 for the fuel exhaust gas and the water recovery device 25 for the assist gas. Water independence in this case means a state in which the amount of water flowing into the water tank 15 from the water recovery device 25 for assist gas is greater than the amount of water flowing out of the water tank 15 to the water evaporator 17, or , the amount of water in the water tank 15 is larger than the predetermined amount.

(Other embodiments)
(1) In each embodiment described above, the control device 21 determines whether or not the water level of the water tank 15 is higher than the determination water level in step S1, thereby determining whether or not the water independence is established. do. However, the control device 21 may determine whether or not the water independence is established by another determination method.

For example, when the amount of water flowing into the water tank 15 is less than the amount of water flowing out of the water tank 15 to the water evaporator 17 and water independence is not established, the water level of the water tank 15 decreases. continue. Therefore, in each of the above-described embodiments, the control device 21 may determine whether or not the water independence is established by determining whether or not the water level obtained from the water level sensor 22 is decreasing. In addition, the control device 21 calculates the rate at which the water level of the water tank 15 descends, and determines whether the calculated rate of decrease is greater than the determination rate, thereby determining whether or not the water independence is established. may

Further, for example, in the first to sixth embodiments, the controller 21 controls the amount of water flowing into the water tank 15 from the water recovery device 19 to be the amount of water flowing out of the water tank 15 to the water evaporator 17. It may be determined whether or not the water independence is established by determining whether or not the number is greater than. In this case, the amount of water flowing into the water tank 15 is measured by a flow meter provided in the flow path of liquid water flowing toward the water tank 15 . The amount of water flowing out of the water tank 15 is calculated from the rotation speed of the water pump 16 or measured by a flow meter provided in the steam supply channel 4 . The water inflow and water outflow of the water tank 15 may be measured by other methods.

Further, for example, in the seventh embodiment, the control device 21 controls the total amount of water flowing into the water tank 15 from both the water recovery device 19 for the combustion exhaust heat gas and the water recovery device 25 for the assist gas. is greater than the outflow of water from the water tank 15 to the water evaporator 17, thereby determining whether or not the water independence is established.

(2) In each of the above-described embodiments, the water tank 15 is supplied with water recovered by at least one of the combustion exhaust water recovery device 19 and the assist gas water recovery device 25 . In addition to the water thus collected, other water present in the fuel cell system 1 may be supplied to the water tank 15 . Other water existing in the fuel cell system 1 is water existing inside the housing housing the fuel cell 2, the reformer 14, etc., and examples thereof include dew condensation water and rain water. Other water present in the fuel cell system 1 does not include water supplied from an external pipe connected to a water source outside the fuel cell system 1 (for example, tap water, well water, etc.). In this case, the amount of water flowing into the water tank 15 from the water collectors 19 and 25 and the portions of the fuel cell system 1 where dew condensation water or rainwater exists flows out from the water tank 15 to the water evaporator 17. A state in which the amount of water in the water tank 15 is greater than the amount of outflow, or a state in which the amount of water in the water tank 15 is greater than a predetermined amount of water is a state in which water independence is established. If the amount of water flowing into the water tank 15 is larger than the amount of water flowing out, the water can be supplied from the water tank 15 to the water evaporator 17 without supplying water to the water tank 15 from the outside of the fuel cell system 1. can be supplied.

(3) In each of the above embodiments, the fuel cell 2 is a solid oxide fuel cell. However, the fuel cell 2 may be another type of fuel cell, such as a molten carbonate fuel cell, as long as it uses a fuel gas reformed by a steam reforming reaction.

(4) In each of the embodiments described above, the control device 21 adjusts the discharge capacity of the raw material pump 12 by changing the rotational speed of the raw material pump 12 . However, the control device 21 may adjust the discharge capacity of the raw material pump 12 by changing the discharge capacity of the raw material pump 12 .

(5) In each of the above-described embodiments, the assist adjustment valve 20 is used as the assist adjustment section. However, a pump that sucks and discharges the assist gas may be used as the assist adjustment unit. In this case, the controller 21 can adjust the flow rate of the assist gas by changing the rotation speed or discharge capacity of the pump.

(6) In each embodiment described above, the control device 21 adjusts the discharge capacity of the water pump 16 by changing the rotation speed of the water pump 16 . However, the discharge capacity of the water pump 16 may be adjusted by changing the discharge capacity of the water pump 16 .

(7) In each embodiment described above, the fuel cell system 1 includes the water pump 16 . However, water can be supplied from the water tank 15 to the water evaporator 17 without the water pump 16 . Therefore, the fuel cell system 1 does not have to include the water pump 16 .

(8) The present invention is not limited to the above-described embodiments, but can be modified as appropriate within the scope of the claims, including various modifications and modifications within the equivalent range. Moreover, the above-described embodiments are not unrelated to each other, and can be appropriately combined unless the combination is clearly impossible. Further, in each of the above-described embodiments, it goes without saying that the elements constituting the embodiment are not necessarily essential, unless it is explicitly stated that they are essential, or they are clearly considered essential in principle. stomach. In addition, in each of the above-described embodiments, when numerical values such as the number, numerical value, amount, range, etc. of the constituent elements of the embodiment are mentioned, when it is explicitly stated that they are particularly essential, and when they are clearly limited to a specific number in principle is not limited to that particular number. In addition, in each of the above-described embodiments, when referring to the material, shape, positional relationship, etc. of the constituent elements, unless otherwise specified or in principle limited to a specific material, shape, positional relationship, etc. , its material, shape, positional relationship, and the like.

(9) The control apparatus and techniques described in the present disclosure may be provided by configuring a processor and memory programmed to perform one or more functions embodied by a computer program. It may be realized by Alternatively, the controller and techniques described in this disclosure may be implemented by a dedicated computer provided by configuring the processor with one or more dedicated hardware logic circuits. Alternatively, the control apparatus and techniques described in this disclosure can be implemented by a combination of a processor and memory programmed to perform one or more functions and a processor configured by one or more hardware logic circuits. It may also be implemented by one or more dedicated computers configured. The computer program may also be stored as computer-executable instructions on a computer-readable non-transitional tangible recording medium.

(summary)
According to the first aspect shown in part or all of the above embodiments, the fuel cell system includes a fuel cell (2) that generates power through an electrochemical reaction using a fuel gas and an oxidant gas; a fuel supply channel (3) for supplying fuel gas to the battery; a raw material pump (12) provided in the fuel supply channel for sucking and discharging the raw material gas that is reformed to become the fuel gas; An ejector (13) provided downstream of the raw material pump in the supply channel and having a nozzle portion (13a), a suction portion (13b) and a discharge portion (13c), and a discharge portion of the ejector in the fuel supply channel. A reformer (14) provided on the downstream side for reforming the raw material gas by a steam reforming reaction to generate a fuel gas; a recycling passageway (10) for returning a part of the fuel gas flowing out of the reformer to the upstream side of the raw material pump in the fuel supply passageway as assist gas. (11), an assist adjustment unit (20) provided in the assist flow path for adjusting the flow rate of the assist gas, and connected between the raw material pump and the ejector in the fuel supply flow path to supply steam to the reformer. a water vapor supply channel (4) for supplying
A water tank (15) connected to the steam supply channel for storing liquid water, and a water evaporator (17) provided in the steam supply channel for evaporating the liquid water sent from the water tank to generate steam. ), a water recovery device (19, 25) for recovering water contained in at least one gas of the combustion exhaust gas and the assist gas generated by burning the fuel off-gas, and supplying the recovered water to the water tank; a judgment unit (S1) for judging whether or not self-reliance is established; and when the judgment unit judges that water self-reliance is not established, the raw material pump is controlled to increase the discharge capacity, and an assist is provided. a flow rate control section (S4) that controls the assist adjustment section so as to increase the gas flow rate.

According to a second aspect, the fuel cell system includes a circulation rate measuring unit (S5) that measures the circulation rate of the recycled gas, which is the ratio of the flow rate of the recycled gas to the flow rate of the fuel off-gas discharged from the fuel cell. and a circulation rate target value setting unit (S2, S3) for setting a target value of the circulation rate. The flow control section controls the raw material pump and the assist adjustment section so that the circulation rate measured by the circulation rate measurement section becomes a target value. The circulation rate target value setting unit raises the target value when the determination unit determines that the water independence is not established. Thus, the configuration of the second aspect can be adopted in the first aspect.

Further, according to a third aspect, in the first or second aspect, the fuel cell system is provided between the water tank and the water evaporator in the steam supply channel, and sucks liquid water. It further comprises a pumping water pump (16). When the determination unit determines that the water independence is not established, the flow rate control unit increases the discharge capacity of the raw material pump, increases the flow rate of the assist gas by the assist adjustment unit, and discharges the water pump. Decrease abilities, and so on, in that order.

Here, if the flow rate of the assist gas is increased by the assist adjustment unit before the discharge capacity of the raw material pump is increased, the flow rate of the raw material gas decreases until the discharge capacity of the raw material pump is increased. If the flow rate of the raw material gas decreases and the flow rate of the raw material gas falls below the target value, the flow rate of the fuel gas required for power generation cannot be ensured, possibly causing damage to the cells of the fuel cell. Therefore, first, the discharge capacity of the raw material pump is increased. As a result, the flow rate of the raw material gas increases once. Next, the assist adjustment unit increases the flow rate of the assist gas. As a result, the flow rate of the raw material gas is reduced to the extent that it does not fall below the target value, and the flow rate of the assist gas is increased. As a result, the flow rate of the raw material gas can always be kept above the target amount.

Further, if the discharge capacity of the water pump is decreased before the discharge capacity of the raw material pump is increased and the flow rate of the assist gas is increased by the assist adjustment unit, the flow rate of the driving flow of the ejector is reduced. In this case, during the period until the discharge capacity of the raw material pump is increased and the flow rate of the assist gas is increased by the assist adjustment section, the power of the ejector is reduced, the flow rate of the recycle gas sucked from the suction section is reduced, and the circulation rate is decreases. If the circulation rate drops, there is a possibility that the flow rate of fuel gas required for power generation cannot be secured. Therefore, by first increasing the flow rate of the assist gas by the assist adjustment unit and then decreasing the discharge capacity of the water pump, it is possible to avoid a decrease in the circulation rate.

Further, according to the fourth aspect, the circulation rate measuring unit calculates the circulation rate using the measurement value of the flow meter (23) provided in the recycling flow path as the flow rate of the recycled gas. Thus, the configuration of the fourth aspect can be adopted in the second aspect.

According to the fifth aspect, the circulation rate measuring unit estimates the flow rate of the recycled gas as the flow rate of the recycled gas based on the measured value of the pressure drop amount of the recycled gas between two points in the recycling flow path. Calculate the circulation rate using the estimated value of Thus, the configuration of the fifth aspect can be adopted in the second aspect.

The recycled gas flowing through the recycling channel is at a high temperature. Therefore, when measuring the flow rate of the recycled gas with a flow meter, the heat resistance of the flow meter becomes an issue. On the other hand, when measuring the pressure drop amount of the recycled gas with a pressure gauge or a differential pressure gauge, the pressure gauge or the differential pressure gauge can be installed so as not to be exposed to the high-temperature recycled gas. Therefore, according to the fifth aspect, such a problem does not occur.

Further, according to the sixth aspect, the circulation rate measuring unit estimates the flow rate of the recycled gas based on the measured value of the pressure drop between the inlet side and the outlet side of the reformer. The estimated flow rate is used to calculate the circulation rate. Thus, the configuration of the sixth aspect can be adopted in the second aspect.

The recycled gas flowing through the recycling channel is at a high temperature. Therefore, when measuring the flow rate of the recycled gas with a flow meter, the heat resistance of the flow meter becomes an issue. On the other hand, when measuring the amount of pressure drop between the inlet side and the outlet side of the reformer with a pressure gauge or the like, the pressure gauge or the like can be installed so as not to be exposed to the high-temperature recycled gas. Therefore, according to the sixth aspect, such a problem does not occur.

By the way, when measuring the amount of pressure drop of the recycled gas between two points in the recycle channel, if the amount of pressure drop of the recycled gas flowing through the recycle channel is small, it is necessary to use a pressure gauge or the like for measuring the amount of pressure drop of the recycled gas. High precision is required. However, if the amount of pressure drop between the inlet side and the outlet side of the reformer is sufficiently large compared to the amount of pressure drop in the recycle flow path, the pressure gauge or the like does not have to be highly accurate.

Further, according to the seventh aspect, the circulation rate measuring unit uses the recycled gas estimated based on the measured value of the pressure drop between the fuel inlet side and the fuel outlet side of the fuel cell as the flow rate of the recycled gas. Calculate the circulation rate using the estimated flow rate. Thus, the configuration of the seventh aspect can be adopted in the second aspect.

The recycled gas flowing through the recycling channel is at a high temperature. Therefore, when measuring the flow rate of the recycled gas with a flow meter, the heat resistance of the flow meter becomes an issue. On the other hand, when measuring the amount of pressure drop between the fuel inlet side and the fuel outlet side of the fuel cell with a pressure gauge or the like, the pressure gauge or the like can be installed so as not to be exposed to the high-temperature recycled gas. Therefore, according to the seventh aspect, such a problem does not arise.

By the way, when measuring the amount of pressure drop in the recycled gas between two points in the recycle channel, if the amount of pressure drop in the recycled gas flowing through the recycle channel is small, the pressure gauge for measuring the amount of pressure drop in the recycled gas will be high. Precision is required. However, if the amount of pressure drop between the fuel inlet side and the fuel outlet side of the fuel cell is sufficiently larger than the amount of pressure drop in the recycle flow path, the pressure gauge and the like may not be highly accurate.

According to the eighth aspect, the circulation rate measuring unit measures the temperature and flow rate of the driving flow flowing into the nozzle of the ejector as the flow rate of the recycle gas, and the driving flow according to the temperature of the driving flow. A circulation rate is calculated using an estimate of the flow rate of the recycle gas, which is estimated based on the relationship between the flow rate of the flow and the flow rate of the suction flow drawn into the suction section. Thus, the configuration of the eighth aspect can be adopted in the second aspect.

According to this, it is sufficient to add a thermometer such as a thermocouple as a measuring instrument for measuring the flow rate of the recycled gas, and it is not necessary to install a pressure gauge. Thermometers, such as thermocouples, are generally less expensive than pressure gauges. Therefore, an increase in cost of the fuel cell system can be suppressed.

According to the ninth aspect, the fuel cell system has a current adjusting device (24) that adjusts the sweep current of the fuel cell, and the judging section judges that the water independence is not established, and the discharge capacity of the raw material pump is determined. is increased, and after the flow rate of the assist gas is increased by the assist adjustment unit, the circulation rate measured by the circulation rate measurement unit does not reach the target value, and the discharge capacity of the raw material pump reaches the maximum. a current control unit (S9) for controlling the current regulator to reduce the . The flow rate control section (S4) controls the raw material pump and the assist adjustment section so that the supply amount of the raw material gas becomes the flow rate corresponding to the sweep current reduced by the current control section and the circulation rate reaches the target value.

After the judging unit judges that the water independence is not established, the discharge capacity of the raw material pump is increased, and the flow rate of the assist gas is increased by the assist adjusting unit, the circulation rate measured by the circulation rate measuring unit reaches the target value. is not reached and the maximum feed capacity of the feed pump is reached, the current flow rate of feed gas cannot increase the circulation rate any further.

Therefore, in this case, in the ninth aspect, the current control section controls the current adjustment device so as to decrease the sweep current. The flow rate controller controls the raw material pump and the assist adjustment section so that the supply amount of the raw material gas becomes a flow rate corresponding to the sweep current reduced by the current control section and the circulation rate reaches the target value. By making the sweep current lower than the current value, the flow rate of the fuel gas required for power generation can be reduced. That is, it is possible to reduce the respective flow rates of the raw material gas and water required for power generation. As a result, the circulation rate can be set to the target value, and water independence can be established.

Further, according to the tenth aspect, the fuel cell system includes a current adjusting device (24) that adjusts the sweep current of the fuel cell, and a determination unit that determines that the water independence is not established, and the discharge capacity of the raw material pump is determined. is increased and the flow rate of the assist gas is increased by the assist adjustment unit, the circulation rate measured by the circulation rate measurement unit does not reach the target value, and the flow rate of the assist gas adjusted by the assist adjustment unit reaches the maximum value. and a current control unit (S9) for controlling the current regulator to decrease the sweep current when it is reached. The flow rate control section (S4) controls the raw material pump and the assist adjustment section so that the supply amount of the raw material gas becomes the flow rate corresponding to the sweep current reduced by the current control section and the circulation rate reaches the target value.

After the judging unit judges that the water independence is not established, the discharge capacity of the raw material pump is increased, and the flow rate of the assist gas is increased by the assist adjusting unit, the circulation rate measured by the circulation rate measuring unit reaches the target value. is not reached and the flow rate of the assist gas adjusted by the assist adjustment unit reaches the maximum, the current flow rate of the raw material gas cannot increase the circulation rate any further.

Therefore, in this case, in the tenth aspect, the current control section controls the current adjustment device so as to decrease the sweep current. The flow rate controller controls the raw material pump and the assist adjustment section so that the supply amount of the raw material gas becomes a flow rate corresponding to the sweep current reduced by the current control section and the circulation rate reaches the target value. By making the sweep current lower than the current value, the flow rate of the fuel gas required for power generation can be reduced. That is, it is possible to reduce the respective flow rates of the raw material gas and water required for power generation. As a result, the circulation rate can be set to the target value, and water independence can be established.

REFERENCE SIGNS LIST 10 recycle channel 11 assist channel 12 raw material pump 13 ejector 14 reformer 15 water tank 17 water evaporator 19 water recovery device for combustion exhaust gas 20 assist adjustment unit 25 water recovery device for assist gas

Claims (10)

A fuel cell system,
a fuel cell (2) that generates electricity through an electrochemical reaction using a fuel gas and an oxidant gas;
a fuel supply channel (3) for supplying the fuel gas to the fuel cell;
a raw material pump (12) provided in the fuel supply channel for sucking and discharging a raw material gas that is reformed to become the fuel gas;
an ejector (13) provided downstream of the raw material pump in the fuel supply channel and having a nozzle portion (13a), a suction portion (13b) and a discharge portion (13c);
a reformer (14) provided in the fuel supply channel downstream of the discharge part of the ejector and configured to reform the raw material gas by a steam reforming reaction to generate the fuel gas;
a recycling flow path (10) for returning part of the fuel off-gas containing the unreacted fuel gas discharged from the fuel cell to the suction portion of the ejector as recycled gas;
an assist channel (11) for returning part of the fuel gas that has flowed out of the reformer to the upstream side of the raw material pump in the fuel supply channel as assist gas;
an assist adjustment unit (20) provided in the assist flow path for adjusting the flow rate of the assist gas;
a steam supply channel (4) connected between the raw material pump and the ejector in the fuel supply channel for supplying steam to the reformer;
a water tank (15) connected to the steam supply channel and storing liquid water;
a water evaporator (17) provided in the water vapor supply channel for evaporating liquid water sent from the water tank to generate water vapor;
a water recovery device (19, 25) for recovering water contained in at least one gas of the combustion exhaust gas generated by burning the fuel off-gas and the assist gas, and supplying the recovered water to the water tank;
a judgment unit (S1) for judging whether or not water self-reliance, which does not require replenishment of water to the water tank from the outside of the fuel cell system, is established;
When the determination unit determines that the water independence is not established, the raw material pump is controlled to increase the discharge capacity, and the assist adjustment unit is controlled to increase the flow rate of the assist gas. and a flow rate control unit (S4). a circulation rate measuring unit (S5) for measuring the circulation rate of the recycled gas, which is the ratio of the flow rate of the recycled gas to the flow rate of the fuel off-gas discharged from the fuel cell;
a circulation rate target value setting unit (S2, S3) that sets the target value of the circulation rate;
The flow rate control unit controls the raw material pump and the assist adjustment unit so that the circulation rate measured by the circulation rate measurement unit becomes the target value,
2. The fuel cell system according to claim 1, wherein said circulation rate target value setting unit increases said target value when said determination unit determines that said water independence is not established. further comprising a water pump (16) provided between the water tank and the water evaporator in the water vapor supply channel for sucking and discharging liquid water;
When the determination unit determines that the water independence is not established, the flow rate control unit increases the discharge capacity of the raw material pump and increases the flow rate of the assist gas by the assist adjustment unit. 3. The fuel cell system according to claim 1, wherein the steps of: and decreasing the discharge capacity of said water pump are performed in this order. 3. The fuel cell system according to claim 2, wherein said circulation rate measuring unit calculates said circulation rate using a measurement value of a flow meter (23) provided in said recycling flow path as said flow rate of said recycled gas. . The circulation rate measuring unit uses, as the flow rate of the recycled gas, an estimated value of the flow rate of the recycled gas that is estimated based on a measured value of a pressure drop amount of the recycled gas between two points in the recycling flow path. 3. The fuel cell system according to claim 2, wherein the circulation rate is calculated by The circulation rate measuring unit uses, as the flow rate of the recycled gas, an estimated value of the flow rate of the recycled gas that is estimated based on the measured value of the pressure drop between the inlet side and the outlet side of the reformer. 3. The fuel cell system according to claim 2, wherein the circulation rate is calculated by The circulation rate measuring unit uses, as the flow rate of the recycled gas, an estimated value of the flow rate of the recycled gas that is estimated based on the measured value of the pressure drop between the fuel inlet side and the fuel outlet side of the fuel cell. 3. The fuel cell system according to claim 2, wherein the circulation rate is calculated using The circulation rate measuring unit measures, as the flow rate of the recycle gas, the measured values of the temperature and the flow rate of the driving flow flowing into the nozzle section of the ejector, and the flow rate of the driving flow according to the temperature of the driving flow. 3. The fuel cell system according to claim 2, wherein the circulation rate is calculated using an estimated value of the flow rate of the recycled gas estimated based on a relationship with the flow rate of the suction flow sucked into the suction portion. a current regulator (24) for regulating the sweep current of the fuel cell;
After the determining unit determines that the water independence is not established, the discharge capacity of the raw material pump is increased, and the flow rate of the assist gas is increased by the assist adjusting unit, the circulation rate measuring unit measures a current control unit (S9) for controlling the current adjusting device to decrease the sweep current when the circulation rate does not reach the target value and the discharge capacity of the raw material pump reaches the maximum. further prepared,
The flow control unit (S4) controls the raw material pump so that the supply amount of the raw material gas becomes a flow rate corresponding to the sweep current reduced by the current control unit, and the circulation rate becomes the target value. 3. The fuel cell system according to claim 2, which controls the assist adjustment section. a current regulator (24) for regulating the sweep current of the fuel cell;
After the determining unit determines that the water independence is not established, the discharge capacity of the raw material pump is increased, and the flow rate of the assist gas is increased by the assist adjusting unit, the circulation rate measuring unit measures current control for controlling the current adjustment device to decrease the sweep current when the circulation rate does not reach the target value and the flow rate of the assist gas adjusted by the assist adjustment unit reaches a maximum. and a part (S9),
The flow control unit (S4) controls the raw material pump so that the supply amount of the raw material gas becomes a flow rate corresponding to the sweep current reduced by the current control unit, and the circulation rate becomes the target value. 3. The fuel cell system according to claim 2, which controls the assist adjustment section.

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