JP2010044997A - Fuel cell system and electronic equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a fuel cell system in which electric power can be generated more stably than a conventional one irrespective of the external environment. <P>SOLUTION: Based on a temperature T1 of a power generation part 10 detected by a temperature detecting part 30, a supply amount of liquid fuel is adjusted by a fuel pump 42, so that the temperature T1 of the power generation part 10 is controlled so as to be constant. By this, compared with conventional systems, for example, this allows a crossover phenomenon to be evaded or fuel supply control in conformity with fluctuations in the external environment to be facilitated. Moreover, the temperature of the power generation part 10 is stabilized. In addition, it is preferable to decide the final supply amount P(s) of the fuel, taking into consideration both the supply amount PPID (s) of the fuel calculated based on the temperature T1 of the power generation part 10 and the supply amount PE (s) of the fuel calculated based on a utilization rate of the fuel. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a fuel cell system that generates electric power by a reaction between methanol or the like and an oxidant gas (oxygen), and an electronic device including such a fuel cell system.

  Conventionally, fuel cells have been put to practical use as industrial or household power generators or power sources for artificial satellites, spacecrafts, and the like because they have high power generation efficiency and do not emit harmful substances. In recent years, development as a power source for vehicles such as passenger cars, buses and trucks has been progressing. Such fuel cells are classified into types such as alkaline aqueous solution type, phosphoric acid type, molten carbonate type, solid oxide type and direct type methanol. In particular, direct methanol solid polymer electrolyte fuel cells (DMFCs) can be increased in energy density by using methanol as a fuel hydrogen source, and they do not require a reformer and can be downsized. Since it is possible, research is being conducted for small portable fuel cells.

  In DMFC, MEA (Membrane Electrode Assembly) which is a unit cell in which a solid polymer electrolyte membrane is sandwiched between two electrodes and integrated and joined is used. When one of the gas diffusion electrodes is used as a fuel electrode (negative electrode) and methanol as fuel is supplied to the surface of the gas diffusion electrode, the methanol is decomposed to generate hydrogen ions (protons) and electrons, and the hydrogen ions are converted into a solid polymer electrolyte. Permeates the membrane. When the other of the gas diffusion electrodes is an oxygen electrode (positive electrode) and air as an oxidant gas is supplied to the surface thereof, oxygen in the air is combined with the hydrogen ions and electrons to generate water. . Due to such an electrochemical reaction, an electromotive force is generated from the DMFC.

  By the way, fuel cells used in mobile applications are required to perform a stable power generation operation in any environment, such as indoors, outdoors in midwinter, high-temperature cars in midsummer, and bags that are difficult to dissipate heat. There is also a need to follow sudden changes in the environment, such as suddenly taking it out of a warm room to the extreme cold. In this way, the fuel cell has an appropriate fuel supply amount that varies depending on the temperature and humidity of the external environment. Therefore, detailed fuel supply control according to environmental fluctuations (fuel supply control that does not cause excess or deficiency in the fuel supply amount) ) Is required.

  Here, when the amount of fuel supply becomes excessive, the surplus fuel penetrates to the oxygen electrode and a phenomenon of crossover occurs. This crossover phenomenon is a phenomenon in which surplus fuel burns directly on the oxygen electrode, which not only reduces the use efficiency of the fuel but is wasted, and may cause burns to the user due to the temperature rise. is there. Conversely, if the fuel supply becomes insufficient, sufficient output cannot be obtained, and power supply to devices connected to the fuel cell may be stopped.

  Therefore, conventionally, a control method of the fuel supply amount for the purpose of suppressing excess and deficiency in the fuel supply amount has been proposed (for example, Patent Document 1).

JP 2007-227336 A

  In the fuel supply control in Patent Document 1, two threshold values (upper limit value and lower limit value) are set for voltage and current, and when the upper limit value is exceeded, fuel supply is stopped, and when the lower limit value is exceeded, fuel supply is resumed. It has become. According to this control method, fuel supply can be controlled by voltage fluctuations during constant current power generation and by current fluctuations during constant voltage power generation.

  However, this control method has a problem that, for example, when a crossover phenomenon occurs, the situation becomes worse. Specifically, for example, when fuel is insufficient during constant current control, the voltage drops and falls below the lower limit, but when the crossover phenomenon occurs, the voltage drops in the same way, so the voltage falls below the lower limit. End up. Here, the fuel must be supplied in the former (when fuel is insufficient), but the fuel supply must be stopped in the latter (when the crossover phenomenon occurs). However, in the conventional fuel supply control, since only the voltage is seen, there is a problem that these differences cannot be distinguished.

  In the DMFC described above, as a method of supplying methanol to the fuel electrode, a liquid supply type (liquid fuel (methanol aqueous solution) is supplied to the fuel electrode as it is) and a vaporization supply type (in a state where the liquid fuel is vaporized). To be supplied to the fuel electrode). Among these, the vaporization supply type cannot perform fuel supply control according to the fuel concentration as in the liquid supply type, and is in a fuel supply cycle (operation timing of the fuel supply pump, shutter opening / closing timing, etc.). The fuel supply is controlled accordingly. Therefore, in particular, in the vaporization supply type DMFC, it has been desired to realize a stable power generation operation independent of the external environment by suppressing excess and deficiency in the fuel supply amount.

  The present invention has been made in view of such problems, and an object thereof is to provide a fuel cell system capable of generating power more stably than before without depending on the external environment, and such a fuel cell system. Is to provide electronic equipment.

  The fuel cell system of the present invention includes a power generation unit that generates power by supplying fuel and oxidant gas, a fuel supply unit that supplies liquid fuel to the power generation unit side, and the supply amount of the liquid fuel is adjustable. The liquid fuel supplied by the fuel supply unit is vaporized to thereby supply the gaseous fuel to the power generation unit, the temperature detection unit for detecting the temperature of the power generation unit, and the temperature detection unit A control unit that controls the temperature of the power generation unit to be constant by adjusting the amount of liquid fuel supplied by the fuel supply unit based on the temperature of the power generation unit.

  An electronic device of the present invention includes the fuel cell system.

  In the fuel cell system and the electronic device of the present invention, the liquid fuel supplied from the fuel supply unit is vaporized in the fuel vaporization unit, whereby the gaseous fuel is supplied to the power generation unit. And in a power generation part, electric power generation is performed by supply of this gaseous fuel and oxidant gas. The temperature of the power generation unit corresponding to such power generation is detected by the temperature detection unit. Then, based on the detected temperature of the power generation unit, the supply amount of the liquid fuel by the fuel supply unit is adjusted, so that the temperature of the power generation unit is controlled to be constant. Here, since the fuel supply amount and the temperature of the power generation unit have a monotonically increasing relationship with each other, for example, the crossover phenomenon is avoided as compared with the conventional fuel supply control based on the generated voltage, generated current, or generated power. Or fuel supply control according to changes in the external environment. Further, since feedback control is performed so that the temperature of the power generation unit becomes constant, the temperature of the power generation unit is stabilized as compared with simple control by turning on (executing) and turning off (stopping) fuel supply.

  According to the fuel cell system or the electronic device of the present invention, the temperature of the power generation unit is controlled to be constant by adjusting the amount of liquid fuel supplied by the fuel supply unit based on the detected temperature of the power generation unit. Therefore, for example, the crossover phenomenon can be avoided or the fuel supply control according to the change in the external environment can be facilitated, and the temperature of the power generation unit can be stabilized. Therefore, it is possible to generate power more stably than before without depending on the external environment.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

[First Embodiment]
FIG. 1 shows the overall configuration of a fuel cell system (fuel cell system 5) according to a first embodiment of the present invention. The fuel cell system 5 supplies power for driving the load 6 via the output terminals T2 and T3. The fuel supply system 5 includes a fuel cell 1, a temperature detector 30, a current detector 31, a voltage detector 32, a booster circuit 33, a secondary battery 34, and a controller 35. .

  The fuel cell 1 includes a power generation unit 10, a fuel tank 40, and a fuel pump 42. The detailed configuration of the fuel cell 1 will be described later.

  The power generation unit 10 is a direct methanol type power generation unit that generates power by a reaction between methanol and an oxidant gas (for example, oxygen), and includes a plurality of unit cells having a positive electrode (oxygen electrode) and a negative electrode (fuel electrode). It consists of The detailed configuration of the power generation unit 10 will be described later.

  The fuel tank 40 contains liquid fuel (for example, methanol or aqueous methanol solution) necessary for power generation. The detailed configuration of the fuel tank 40 will be described later.

  The fuel pump 42 is a pump for pumping the liquid fuel stored in the fuel tank 40 and supplying (transporting) the liquid fuel to the power generation unit 10 side. The fuel pump 42 can adjust the fuel supply amount. The operation of the fuel supply pump 42 (liquid fuel supply operation) is controlled by a control unit 35 described later. The detailed configuration of the fuel pump 42 will be described later.

  The temperature detection unit 30 detects the temperature T1 of the power generation unit 10 (specifically, the temperature around or near the power generation unit 10) T1, and is configured by a thermistor, for example.

  The current detection unit 31 is disposed between the positive electrode side of the power generation unit 10 and the connection point P1 on the connection line L1H, and detects the power generation current I1 of the power generation unit 10. The current detection unit 31 includes a resistor, for example. Such a current detection unit 31 may be disposed on the connection line L1L (between the negative electrode side of the power generation unit 10 and the connection point P2).

  The voltage detection unit 32 is disposed between the connection point P1 on the connection line L1H and the connection point P2 on the connection line L1L, and detects the power generation voltage V1 of the power generation unit 10. The voltage detection unit 32 includes a resistor, for example.

  The booster circuit 33 is disposed between the connection point P1 on the connection line L1H and the connection point P3 on the output line LO, and boosts the power generation voltage V1 (DC voltage) of the power generation unit 10 to generate a DC voltage. It is a voltage conversion part which produces | generates V2. The booster circuit 33 is constituted by, for example, a DC / DC converter.

  The secondary battery 34 is disposed between the connection point P3 on the output line LO and the connection point P4 on the ground line LG, and stores power based on the DC voltage V2 generated by the booster circuit 33. It is. The secondary battery 34 is composed of, for example, a lithium ion secondary battery.

  The control unit 35 includes a power generation unit temperature (detection temperature) T1 detected by the temperature detection unit 30, a power generation current (detection current) I1 detected by the current detection unit 31, and a power generation detected by the voltage detection unit 32. The supply amount of the liquid fuel by the fuel pump 42 is adjusted based on the voltage (detection voltage) V1. Specifically, particularly in the present embodiment, the temperature of the power generation unit 10 is kept constant (substantially approximately) by adjusting the amount of liquid fuel supplied by the fuel pump 42 based on the detected temperature T1 detected by the temperature detection unit 30. The control is performed so as to be within a predetermined range. The control unit 35 is configured by, for example, a microcomputer. The detailed configuration and detailed operation of the control unit 35 will be described later.

  Next, the detailed configuration of the fuel cell 1 will be described with reference to FIGS. 2 and 3 show configuration examples of the unit cells 10A to 10F in the power generation unit 10 in the fuel cell 1, and FIG. 2 corresponds to a cross-sectional configuration taken along line II-II in FIG. To do. The unit cells 10 </ b> A to 10 </ b> F are arranged in, for example, 3 rows × 2 columns in the in-plane direction, and have a planar laminated structure electrically connected in series by a plurality of connection members 20. A terminal 20A, which is an extension of the connection member 20, is attached to the unit cells 10C and 10F. A fuel tank 40, a fuel pump 42, a nozzle 43, and a fuel vaporization unit 44 are provided below the unit cells 10A to 10F.

  Each of the unit cells 10A to 10F has a fuel electrode (negative electrode, anode electrode) 12 and an oxygen electrode 13 (positive electrode, cathode electrode) arranged to face each other with the electrolyte membrane 11 therebetween.

The electrolyte membrane 11 is made of, for example, a proton conductive material having a sulfonic acid group (—SO ₃ H). Examples of proton conducting materials include polyperfluoroalkylsulfonic acid proton conducting materials (for example, “Nafion (registered trademark)” manufactured by DuPont), hydrocarbon proton conducting materials such as polyimide sulfonic acid, or fullerene proton conducting materials. Is mentioned.

  The fuel electrode 12 and the oxygen electrode 13 have a configuration in which a catalyst layer containing a catalyst such as platinum (Pt) or ruthenium (Ru) is formed on a current collector made of, for example, carbon paper. The catalyst layer is made of, for example, a material in which a carrier such as carbon black carrying a catalyst is dispersed in a polyperfluoroalkylsulfonic acid proton conductive material or the like. Note that an air supply pump (not shown) may be connected to the oxygen electrode 13 or communicate with the outside through an opening (not shown) provided in the connection member 20 to supply air, that is, oxygen by natural ventilation. You may come to be.

  The connecting member 20 has a bent portion 23 between the two flat portions 21 and 22. The connecting member 20 is in contact with the fuel electrode 12 of one unit cell (for example, 10A) in one flat portion 21 and in the other flat portion 22. It is in contact with the oxygen electrode 13 of the adjacent unit cell (for example, 10B), and two adjacent unit cells (for example, 10A, 10B) are electrically connected in series and generated in each of the unit cells 10A to 10F. It also has a function as a current collector for collecting electricity. Such a connection member 20 has, for example, a thickness of 150 μm and is made of copper (Cu), nickel (Ni), titanium (Ti), or stainless steel (SUS), such as gold (Au) or platinum (Pt). It may be plated with. The connecting member 20 has openings (not shown) for supplying fuel and air to the fuel electrode 12 and the oxygen electrode 13, respectively. For example, the connecting member 20 is made of mesh such as expanded metal, punching metal, or the like. It is configured. The bent portion 23 may be bent in advance according to the thickness of the unit cells 10A to 10F, or in the manufacturing process when the connecting member 20 has flexibility such as a mesh having a thickness of 200 μm or less. It may be formed by bending. Such a connecting member 20 is formed by, for example, screwing a sealing material (not shown) such as PPS (polyphenylene sulfide) or silicone rubber provided around the electrolyte membrane 11 to the connecting member 20. The unit cells 10A to 10F are joined.

  The fuel tank 40 includes, for example, a container (for example, a plastic bag) whose volume changes without bubbles or the like even when the liquid fuel 41 increases or decreases, and a rectangular parallelepiped case (structure) that covers the container. Has been. The fuel tank 40 is provided with a fuel pump 42 for sucking the liquid fuel 41 in the fuel tank 40 and discharging it from the nozzle 43 near the center.

  The fuel pump 42 is, for example, a flow as a pipe connecting a piezoelectric body (not shown), a piezoelectric support resin portion (not shown) for supporting the piezoelectric body, and the fuel tank 40 to the nozzle 43. And a road (not shown). For example, as shown in FIG. 4, the fuel pump 42 can adjust the fuel supply amount in accordance with the change in the fuel supply amount per operation or the fuel supply cycle Δt. . The fuel pump 42 corresponds to a specific example of “fuel supply unit” in the present invention.

  The fuel vaporization unit 44 supplies gaseous fuel to the power generation unit 10 (each unit cell 10A to 10F) by vaporizing the liquid fuel supplied by the fuel pump 42. The fuel vaporization section 44 is used to promote the diffusion of fuel on a plate (not shown) made of a highly rigid resin material such as a metal or alloy including stainless steel, aluminum, or cycloolefin copolymer (COC). The diffusion part (not shown) is provided. As the diffusion portion, an inorganic porous material such as alumina, silica, titanium oxide, or a resin porous material can be used.

  The nozzle 43 is a fuel ejection port that is transported by a flow path (not shown) of the fuel pump 42, and ejects fuel toward a diffusion portion provided on the surface of the fuel vaporization portion 44. Yes. Thereby, the fuel transported to the fuel vaporization unit 44 is diffused and vaporized and supplied toward the power generation unit 10 (unit cells 10A to 10F). The nozzle 43 has a diameter of 0.1 mm to 0.5 mm, for example.

  Next, a detailed configuration of the control unit 35 will be described with reference to FIG. FIG. 5 shows a detailed block configuration of the control unit 35.

  The control unit 35 includes a subtraction unit (difference calculation unit) 350, a PID control unit 351, and a heat generation correction unit 352.

  The subtraction unit 350 is set in advance in the control unit 35 or is input from the outside (target temperature (set temperature) Tsv (s)), and the temperature (detected temperature) T1 of the power generation unit 10 detected by the temperature detection unit 30. A difference value (= Tsv (s) −Tpv (s)) from (Tpv (s)) is obtained, and this difference value is output to the PID control unit 351.

  The PID control unit 351 is proportional to the time integral value and the time differential value of the difference value between the target temperature Tsv (s) and the detected temperature Tpv (s) obtained by the subtraction unit 350, thereby A supply amount (desired heat generation amount H (s)) is calculated, and the desired heat generation amount H (s) is output to the heat generation correction unit 352.

Specifically, the PID control unit 351 calculates the desired heat generation amount H (s) using the following equations (1) and (2).
H (s) = K _P ΔT (s) + T _I ∫ΔT (s) ds + T _D {dΔT (s) / ds} (1)
ΔT (s) = Tsv (s) −Tpv (s) (2)
here,
H (s): the desired heating value _{K P, T I, T D} : PID constants Tsv (s): the target temperature [Delta] T (s): Temperature of the difference s: Time

  The heat generation correction unit 352 calculates the energy conversion efficiency in the power generation unit 10 based on the power generation voltage (detection voltage) V1 detected by the voltage detection unit 32 and the power generation current (detection current) I1 detected by the current detection unit 31. In addition, the fuel supply amount P (s) is calculated using the calculated energy conversion efficiency (the liquid fuel supply amount calculated by the PID control unit 351 is corrected). Information on the fuel supply amount P (s) is output to the fuel pump 42 in the fuel cell 1. Thereby, although mentioned later for details, the temperature of the electric power generation part 10 becomes fixed.

Specifically, the heat generation correction unit 352 calculates the fuel supply amount P (s) using the following equations (3) and (4). In the present embodiment, the energy conversion efficiency η in the power generation unit 10 is calculated in consideration of the power generation current I1 of the power generation unit 10 in addition to the power generation voltage V1 of the power generation unit 10, but the fuel utilization rate By performing an approximation that E is approximately 1, the energy conversion efficiency η in the power generation unit 10 may be approximately calculated (η≈V _O / V _T ). In actual control, even if such approximate calculation is performed, there is almost no influence on the control operation.
P (s) (= P _PID (s)) = H (s) × (1-η) (3)
η = {(V _O I _O ) / (V _T I _T )} = (V _O / V _T ) × E (4)
_IT : Theoretical current value estimated from the fuel supply

  The fuel cell system 5 of the present embodiment can be manufactured as follows, for example.

  First, the fuel electrode 12 and the oxygen electrode 13 are joined to the electrolyte membrane 11 by thermocompression bonding the electrolyte membrane 11 made of the above-described material between the fuel electrode 12 and the oxygen electrode 13 made of the above-described material, Unit cells 10A to 10F are formed.

  Next, a connecting member 20 made of the above-described material is prepared, and as shown in FIGS. 6 and 7, six unit cells 10A to 10F are arranged in 3 rows × 2 columns and electrically connected by the connecting member 20. Connect in series. A sealing material (not shown) made of the above-described material is provided around the electrolyte membrane 11, and the sealing material is fixed to the bent portion 23 of the connecting member 20 by screwing.

  After that, by arranging the fuel tank 40 in which the liquid fuel 41 is accommodated and the fuel pump 42 and the nozzle 43 are provided on the fuel electrode 12 side of the connected unit cells 10A to 10F, the fuel cell 1 is provided. Form. The temperature detector 30, current detector 31, voltage detector 32, booster circuit 33, secondary battery 34, and controller 35 described above are electrically connected to the fuel cell 1 as shown in FIG. Install in parallel. Thus, the fuel cell system 5 shown in FIGS. 1 to 3 is completed.

  Next, the operation and effect of the fuel cell system 5 of the present embodiment will be described in detail in comparison with a comparative example.

  In the fuel cell system 5, the liquid fuel stored in the fuel tank 40 is pumped up by the fuel pump 42 and reaches the fuel vaporization unit 44 through a flow path (not shown). In the fuel vaporization section 44, when the liquid fuel is ejected by the nozzle 43, it is diffused over a wide range by a diffusion section (not shown) provided on the surface thereof. Thereby, the liquid fuel is naturally vaporized, and the gaseous fuel is supplied to the power generation unit 10 (specifically, the fuel electrode 12 of each of the unit cells 10A to 10F).

On the other hand, air (oxygen) is supplied to the oxygen electrode 13 of the power generation unit 10 by natural ventilation or an air supply pump (not shown). Then, in the oxygen electrode 13, the reaction shown in the following formula (5) occurs, and hydrogen ions and electrons are generated. The hydrogen ions reach the fuel electrode 12 through the electrolyte membrane 11, and the reaction shown in the following formula (6) occurs in the fuel electrode 12 to generate water and carbon dioxide. Accordingly, the fuel cell 1 as a whole undergoes the reaction shown in the following formula (7), and power generation is performed.
_{CH 3 OH + H 2 O →} CO 2 + 6H + + 6e - ...... (5)
6H ⁺ + (3/2) O ₂ + 6e ⁻ → 3H ₂ O ...... (6)
CH ₃ OH + (3/2) O ₂ → CO ₂ + 2H ₂ O (7)

  Thereby, a part of the chemical energy of the liquid fuel 41, that is, methanol, is converted into electric energy, collected by the connecting member 20, and taken out from the power generation unit 10 as a current (generated current I1). The generated voltage (DC voltage) V1 based on the generated current I1 is boosted (voltage converted) by the booster circuit 33 to become a DC voltage V2. The DC voltage V2 is supplied to the secondary battery 34 or a load (for example, an electronic device main body). When the DC voltage V2 is supplied to the secondary battery 34, the secondary battery 34 is charged based on this voltage, while the DC voltage V2 is supplied to the load 6 through the output terminals T2 and T3. In this case, the load 6 is driven and a predetermined operation is performed. At this time, in the fuel pump 42, the fuel supply amount is adjusted according to the change in the fuel supply amount per one operation or the fuel supply cycle Δt by the control of the control unit 35.

  Here, in the conventional fuel supply control according to Comparative Example 1, the above-described fuel supply cycle Δt is always constant. In this case, a loop of “output increase → temperature increase → drying of electrolyte membrane 11 → output decrease → temperature decrease → wetting of electrolyte membrane 11 →...” Is repeated endlessly. Therefore, for example, as shown in FIG. 8, the power generation output and temperature greatly oscillate despite the fuel supply being at regular intervals.

  Further, in the conventional fuel supply control according to Comparative Example 2, two threshold values (upper limit value and lower limit value) are set for the generated voltage at the time of constant current power generation control and the generated current at the time of constant voltage power generation control, exceeding the upper limit value. Then, the fuel supply is stopped. On the other hand, the fuel supply is resumed when it falls below the lower limit. However, the fuel supply amount and the power generation voltage, the power generation current, and the power generation output that is the product of them do not show a monotonous change as shown in FIG. 9, for example. It draws a mountain-like curve with local maxima. Therefore, for example, when the generated voltage is low, there is no way of knowing whether or not the maximum value (threshold value) has been exceeded at that time, so it is not possible to correctly determine whether the fuel supply should be increased or decreased. Specifically, for example, when a crossover phenomenon occurs, it will be made even worse. That is, for example, if the fuel is insufficient during constant current control, the voltage drops and falls below the lower limit value, but when the crossover phenomenon occurs, the voltage drops in the same manner and falls below the lower limit value. Here, the fuel must be supplied in the former (when fuel is insufficient), but the fuel supply must be stopped in the latter (when the crossover phenomenon occurs). However, in the fuel supply control of Comparative Example 2, since only the voltage is seen, these differences cannot be distinguished.

  On the other hand, in the fuel cell system 5 of the present embodiment, as shown in FIGS. 1 and 5, the temperature (detected temperature) T1 of the power generation unit 10 is detected by the temperature detection unit 30, and this Based on the detected temperature T1, the supply amount of the liquid fuel by the fuel pump 42 is adjusted by the control unit 35. Here, the fuel supply amount and the temperature of the power generation unit are different from the above-described power generation voltage and the like, and have a monotonically increasing relationship as shown in FIG. 10, for example.

  Thereby, compared with the fuel supply control based on the generated voltage or the like as in Comparative Example 1, for example, the crossover phenomenon can be avoided or the fuel supply control according to the fluctuation of the external environment becomes easier (for example, in FIG. This makes it easier to define thresholds as shown). Specifically, when the detected temperature T1 is too high, the fuel supply is always reduced. Conversely, when the detected temperature T1 is too low, the fuel supply is always increased. According to this principle, there is no failure situation, so it is possible to continue stable and robust power generation.

  In the first place, fuel cells generate electricity through chemical reactions. A fuel oxidation reaction proceeds at the fuel electrode, and an oxidant reduction reaction proceeds at the oxygen electrode. Therefore, controlling power generation is nothing other than controlling these chemical reactions themselves. Here, according to the chemical reaction kinetics, the parameters that determine the chemical reaction rate are the frequency factor, the activation energy, and the temperature. Considering that the former two are almost constant, it is understood that it is important to stabilize the temperature in order to stabilize the chemical reaction of the fuel cell. Therefore, also from such a viewpoint, stable power generation is realized by stabilizing the temperature, which is a fundamental control parameter for determining the generated current.

  However, when performing fuel supply based on the detected temperature T1, simple control of stopping the fuel supply when the upper limit temperature is exceeded and restarting the fuel supply when the temperature falls below the lower limit temperature is not preferable. In this case, similarly to the temperature control by the thermostat using the bimetal, there is a high possibility that the temperature vibrates greatly as in the comparative example 3 shown in FIGS. 11A and 11B, for example. That is, if the fuel supply is stopped after exceeding the upper limit temperature, it is too late, and the temperature T1 of the power generation unit 10 further increases. Conversely, even if the fuel supply is resumed after the temperature falls below the lower limit temperature, it is too late. The temperature T1 of the part 10 will further decrease.

  Therefore, in the fuel cell system 5 of the present embodiment, as shown in FIG. 5, feedback control (specifically, PID control) is performed by the PID control unit 351 so that the temperature of the power generation unit 10 becomes constant. It has been made. This PID control is one of the classic feedback control methods that can quickly bring the control amount close to the target value and stabilize it, and is a control method that makes it possible to approach the actual target value smoothly. .

  As a result, for example, as shown in FIGS. 12A and 12B, overshoot and undershoot at the temperature of the power generation unit 10 are prevented, and the fuel supply is turned on (executed) described in Comparative Example 3 above. -The temperature of the electric power generation part 10 is stabilized compared with the simple control by OFF (stop). Therefore, for example, as shown in FIG. 13, it has been found that the power generation operation is stably performed in the power generation unit 10 by the fuel supply control of the present embodiment.

  For example, in the embodiment shown in FIGS. 14A to 14D, the calculated fuel supply amount is not supplied as it is, but a power generation test is performed by adding noise to the calculation result (noise). (Results of power generation when there is no noise → noise) From FIG. 14, it can be seen that even if noise is added, the power generation output is hardly affected and power generation continues stably. In a fuel cell system that uses a fuel pump as a fuel supply means, there is a possibility that the ejection amount changes due to deterioration with time or disturbance of the fuel pump. However, the results shown in FIG. 14 indicate that power generation continues stably even if the ejection amount of the fuel pump changes unexpectedly.

  Further, for example, the embodiment shown in FIGS. 15A to 15D is a case where the fuel supply amount is suddenly and drastically changed (here, suddenly lowered). From FIG. 15, it can be seen that even if the fuel supply amount is suddenly and drastically changed, the fluctuation can be almost absorbed by the PID control.

  Further, for example, the embodiment shown in FIGS. 16A to 16C is a case where bubbles are mixed in the liquid fuel. FIG. 16 shows that even when some air is mixed into the fuel electrode, the fluctuation can be almost absorbed by the PID control.

  As described above, in the present embodiment, the temperature T1 of the power generation unit 10 is adjusted by adjusting the amount of liquid fuel supplied by the fuel pump 42 based on the temperature T1 of the power generation unit 10 detected by the temperature detection unit 30. Since constant control is performed, for example, crossover phenomenon can be avoided or fuel supply control according to fluctuations in the external environment can be facilitated, and the temperature of the power generation unit 10 can be stabilized. . Therefore, it is possible to generate power more stably than in the past, regardless of the external environment (for example, deterioration with time or disturbance).

  Specifically, in the PID control unit 351, the supply amount of the liquid fuel is proportional to the time integral value and the time differential value of the difference value between the target temperature Tsv (s) and the detected temperature T1 (Tpv (s)). By doing so, the control is performed so that the temperature of the power generation unit 10 becomes constant, and thus the above-described effects can be obtained.

  In addition, the heat generation correction unit 352 calculates the energy conversion efficiency η in the power generation unit 10 based on the power generation voltage V1 detected by the voltage detection unit 32 and the power generation current I1 detected by the current detection unit 31. Since the supply amount of the liquid fuel is corrected using the energy conversion efficiency η, fuel supply control in consideration of the energy conversion efficiency η is possible, and it is possible to perform more stable power generation than in the past.

  Furthermore, even in a vaporization supply type DMFC, which has been particularly desired to have a stable power generation operation that does not depend on the external environment, it is possible to generate power more stably than in the past by suppressing excess and deficiency in the amount of fuel supply. .

[Second Embodiment]
Next, a second embodiment of the present invention will be described. The fuel cell system of the present embodiment is such that a control unit 36 described later is provided in place of the control unit 35 in the fuel cell system 5 of the first embodiment shown in FIG. In addition, the same code | symbol is attached | subjected to the same thing as the component in 1st Embodiment, and description is abbreviate | omitted suitably.

  FIG. 17 illustrates a block configuration of the control unit 36 of the present embodiment. The control unit 36 includes a subtraction unit (difference calculation unit) 350, a PID control unit 351, a heat generation correction unit 352, a utilization rate control unit 361, and a minimum value selection unit 362. That is, in the control unit 35 of the first embodiment shown in FIG. 5, a utilization rate control unit 361 and a minimum value selection unit 362 are further provided.

Based on the generated current (detected current) I 1 detected by the current detector 31, the utilization rate control unit 361 is estimated from the fuel utilization rate E (= actual generated current value I _O / fuel supply amount) in the power generation unit 10. Calculated theoretical current value I _T ), and the liquid fuel supply amount P _E (s) is calculated so that the calculated fuel utilization rate E is maintained (so as to be constant). . Note that the usage rate E of the fuel, 6e methanol per molecule ^- since the charge is removed, which is calculated on the basis of this relationship, the measured current (here, the detected current I1) to the theoretical maximum current ratio of Means.

Specifically, the utilization rate control unit 361 calculates the fuel supply amount P _E (s) using the following equation (8).
P _E (s) = Kcell × Esv × Ipv (s) (8)
(Kcell: proportional constant, Esv: set value of utilization rate, Ipv (s): current generated current value)

The minimum value selection unit 362 uses the PID control unit 351 and the heat generation correction unit 352 to calculate the fuel supply amount P _PID (s) (first fuel supply amount) calculated based on the temperature T1 of the power generation unit 10 and the utilization rate. The control unit 361 determines the final fuel supply amount P (s) in consideration of the fuel supply amount P _E (s) (second fuel supply amount) calculated based on the fuel utilization rate E. The fuel is supplied to the fuel pump 42 in the fuel cell 1. Specifically, the final fuel supply amount P (s) is determined by selecting one of the fuel supply amount P _PID (s) and the fuel supply amount P _E (s). Yes. More specifically, the final fuel supply amount P (s) is determined by selecting the smaller one of the fuel supply amount P _PID (s) and the fuel supply amount P _E (s). It comes to decide.

Instead of the selection method in the minimum value selection unit 36, another selection method may be used. For example, by selecting one of the fuel supply amount P _PID (s) and the fuel supply amount P _E (s) according to the type of power generation mode in the power generation unit 10, the final fuel supply amount P ( s) may be determined.

  Next, the operation and effect of the fuel cell system of the present embodiment will be described in detail. Since the basic operation of the fuel cell system is the same as that of the first embodiment, only the fuel supply control operation by the control unit 36 will be described.

  First, in the control unit 35 of the first embodiment described above, for example, when the fuel cell 1 during power generation is suddenly cooled, a large high heat generation phenomenon occurs as shown in FIG. 18, for example. There can be. This is because the target temperature is always constant, so if it continues to be cooled from the outside and cannot reach the target temperature, it will try to approach the target temperature even if excessive fuel is supplied and crossover occurs. It is. In other words, it is a situation where power generation is not possible, but it is not recognized.

Therefore, for example, as in the control unit 106 (Comparative Example 4) shown in FIG. 19, the above-described utilization rate control unit 361 is provided in the control unit 106, and the liquid fuel is controlled so that the calculated utilization rate of fuel becomes constant. It is conceivable to adjust the supply amount P _E (s). This is because, for example, even when sudden cooling or the like occurs, it is considered possible to follow environmental changes.

  In the fuel supply control of Comparative Example 4, for example, as shown in FIGS. 20 (A) to 20 (C), when power is generated and cooled around the power generation unit 10 during power generation (sudden cooling is performed). Even if it occurs, it can be seen that power generation continues without the utilization rate decreasing (maintained at about 50%). However, as shown in FIG. 20C, the temperature of the power generation unit 10 rises to a maximum of nearly 60 ° C., and a high temperature phenomenon has occurred.

In contrast, in the control unit 36 of the present embodiment, the PID control unit 351 and the heat generation correction unit 352 calculate the fuel supply amount P _PID (s) calculated based on the temperature T1 of the power generation unit 10 and the utilization rate. In the control unit 361, the final fuel supply amount P (s) is determined in consideration of both the fuel supply amount P _E (s) calculated based on the fuel utilization rate. . That is, the advantage in the PID control in which the temperature of the heat generating unit 10 is constant and the advantage in the utilization rate control in which the utilization rate of the heat generating unit 10 is constant are combined, so that the respective disadvantages are offset.

  Thereby, for example, when sudden cooling or the like occurs, the utilization rate E of the power generation unit 10 becomes constant, thereby avoiding a high heat generation phenomenon in the case of PID control and an upper limit on the temperature of the power generation unit 10. Since it is provided, the high temperature phenomenon in the case of utilization rate control is avoided.

  Therefore, for example, as shown in FIGS. 21 (A) to 21 (D), even when wind is passed around the power generation unit 10 to cool it, abnormal heat generation due to crossover does not occur and safe power generation is performed. I understand that For example, as shown in FIGS. 22 (A) to 22 (D), even when the bottom of the power generation unit 10 is directly cooled, abnormal heat generation due to the crossover is not generated, and safe power generation is performed. I understand that.

As described above, in the present embodiment, in the PID control unit 351 and the heat generation correction unit 352, the fuel supply amount P _PID (s) calculated based on the temperature T1 of the power generation unit 10 and the utilization rate control unit 361 The final fuel supply amount P (s) is determined in consideration of both the fuel supply amount P _E (s) calculated based on the fuel utilization rate E. A high heat generation phenomenon and a high temperature phenomenon in the case of utilization rate control can be avoided. Therefore, compared to the first embodiment, it is possible to generate power stably even under various changes in the external environment.

Specifically, the minimum fuel supply amount P _PID (s) and the fuel supply amount P _E (s) are selected by the minimum value selector 362 to select the final fuel supply amount. Since P (s) is determined, the effects as described above can be obtained.

  Further, by combining the PID control and the utilization rate control, it is possible to define the upper limit value (Tmax) of the temperature of the power generation unit 10 and the lower limit value (Emin) of the utilization rate, which is safe against various disturbances. Thus, it is possible to realize a robust power generation operation.

(Modification of the second embodiment)
In the fuel supply control of the second embodiment (combination of PID control and usage rate control), if the setting of the lower limit value of the usage rate E is inappropriate, sufficient power output cannot be obtained, On the other hand, there is a possibility that fuel will be consumed wastefully. In addition, the case where the setting of the lower limit value of the utilization rate E is inappropriate is specifically the case where the setting of the lower limit value of the utilization rate E is not suitable for the external environment, the failure of the fuel supply system, etc. For example, the fuel supply amount per operation of the fuel pump 42 fluctuates due to the above. Therefore, it is preferable that the set value (here, the lower limit value) of the fuel utilization rate E is periodically (dynamically) updated in the control unit 36 according to the environment. Specifically, for example, the fuel is completely consumed every 10 minutes, and the actual value of the fuel utilization rate E in the past 10 minutes is calculated each time. Then, the lower limit value of the utilization rate E is automatically updated so that the calculated utilization rate E is maintained even in the next 10 minutes.

  When configured in this manner, for example, as shown in FIGS. 23A to 23F, not only safety but also energy conversion efficiency η (fuel consumption) can be optimized.

  While the present invention has been described with reference to the first and second embodiments and modifications, the present invention is not limited to these embodiments and the like, and various modifications are possible.

  For example, in the above-described embodiment, the amount of liquid fuel supplied is proportional to the time integral value and the time differential value of the difference value between the target temperature Tsv (s) and the detected temperature Tpv (s). The case where the control is performed so that the temperature of the unit 10 is constant (PID control is performed) has been described. For example, the power generation is performed using other feedback control such as P control, PI control, fuzzy control, and H∞ control. You may make it control so that the temperature of the part 10 becomes fixed. Specifically, the control is performed so that the temperature of the power generation unit 10 becomes constant by making the supply amount of the liquid fuel proportional to the difference value between the target temperature Tsv (s) and the detected temperature Tpv (s). It may be performed (P control is performed). Further, the supply amount of the liquid fuel is controlled to be proportional to the time integral value of the difference value between the target temperature Tsv (s) and the detected temperature Tpv (s) so that the temperature of the power generation unit 10 becomes constant. (PI control) may be performed. Further, the supply amount of the liquid fuel is proportional to the time differential value of the difference value between the target temperature Tsv (s) and the detected temperature Tpv (s), so that the temperature of the power generation unit 10 is controlled to be constant. (PD control) may be performed.

  In the above-described embodiment and the like, the case where the heat generation correction unit 352 calculates the energy conversion efficiency η in the power generation unit 10 using the power generation voltage (detected voltage) V1 detected by the voltage detection unit 32 has been described. The energy conversion efficiency η in the power generation unit 10 may be calculated using a predetermined voltage (set voltage) set in advance instead of the power generation voltage V1.

  Moreover, although the said embodiment etc. demonstrated the case where the electric power generation part 10 included six unit cells electrically connected mutually in series, the number of unit cells is not restricted to this. For example, the power generation unit 10 may be configured with one unit cell, or may be configured with two or more arbitrary unit cells.

  In the above-described embodiment and the like, the supply of air to the oxygen electrode 13 is natural ventilation, but it may be forcibly supplied using a pump or the like. In that case, oxygen or a gas containing oxygen may be supplied instead of air.

  In the above-described embodiment and the like, the case where the fuel tank 40 that stores the liquid fuel 41 is built in the fuel cell system 5 has been described. However, such a fuel tank can be attached to and detached from the fuel cell system. It is good.

  In the above-described embodiments and the like, the direct methanol type fuel cell system has been described. However, the present invention can be applied to other types of fuel cell systems.

The fuel cell system of the present invention can be suitably used for portable electronic devices such as a mobile phone, an electrophotographic machine, an electronic notebook, or a PDA (Personal Digital Assistants).

1 is a block diagram illustrating an overall configuration of a fuel cell system according to a first embodiment of the present invention. It is sectional drawing showing the structural example of the electric power generation part shown in FIG. It is a top view showing the structural example of the electric power generation part shown in FIG. It is a characteristic view for demonstrating the outline | summary of a vaporization type fuel supply system. It is a block diagram for demonstrating the detailed structure of the control part shown in FIG. It is sectional drawing for demonstrating the manufacturing method of the electric power generation part shown in FIG. It is a top view for demonstrating the manufacturing method of the electric power generation part shown in FIG. 10 is a characteristic diagram illustrating an example of power generation characteristics by fuel supply control according to Comparative Example 1. FIG. It is a schematic characteristic diagram for demonstrating the electric power generation characteristic by the fuel supply control which concerns on the comparative example 2. FIG. It is a schematic characteristic diagram for demonstrating the outline | summary of the electric power generation characteristic by the fuel supply control which concerns on 1st Embodiment. It is a schematic characteristic diagram for demonstrating the electric power generation characteristic by the fuel supply control which concerns on the comparative example 3. FIG. It is a schematic characteristic diagram for demonstrating the detail of the electric power generation characteristic by the fuel supply control which concerns on 1st Embodiment. It is a characteristic view showing an example of the electric power generation characteristic by fuel supply control concerning a 1st embodiment. It is a characteristic view showing the other example of the electric power generation characteristic by the fuel supply control which concerns on 1st Embodiment. It is a characteristic view showing the other example of the electric power generation characteristic by the fuel supply control which concerns on 1st Embodiment. It is a characteristic view showing the other example of the electric power generation characteristic by the fuel supply control which concerns on 1st Embodiment. It is a block diagram for demonstrating the detailed structure of the control part which concerns on 2nd Embodiment. It is a characteristic view for demonstrating the high heat_generation | fever which may arise in the fuel supply control which concerns on 1st Embodiment. 10 is a block diagram for explaining a detailed configuration of a control unit according to Comparative Example 4. FIG. 10 is a characteristic diagram illustrating an example of power generation characteristics by fuel supply control according to Comparative Example 4. FIG. It is a characteristic view showing an example of the electric power generation characteristic by fuel supply control concerning a 2nd embodiment. It is a characteristic view showing the other example of the electric power generation characteristic by the fuel supply control which concerns on 2nd Embodiment. It is a characteristic view showing an example of the electric power generation characteristic by fuel supply control concerning the modification of a 2nd embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Fuel cell, 10 ... Electric power generation part, 10A-10F ... Unit cell, 11 ... Electrolyte membrane, 12 ... Fuel electrode, 13 ... Oxygen electrode, 20 ... Connection member, 20A ... Terminal, 30 ... Temperature detection part, 31 ... Current Detection unit, 32 ... Voltage detection unit, 33 ... Boost circuit, 34 ... Secondary battery, 35, 36 ... Control unit, 350 ... Subtraction unit (difference calculation unit), 351 ... PID control unit, 352 ... Heat generation correction unit, 361 ... usage rate control unit, 362 ... minimum value selection unit, 40 ... fuel tank, 41 ... liquid fuel, 42 ... fuel pump, 43 ... nozzle, 44 ... fuel vaporization unit, 5 ... fuel cell system, 6 ... load, V1 ... Generated voltage (detected voltage), V2 ... DC voltage, I1 ... generated current (detected current), T1 (Tpv (s)) ... detected temperature, Tsv (s) ... target temperature, H (s) ... desired heating value, P _{(s), P PID (s} ), P E (s) ... fuel supply Supply amount (fuel injection amount), P1 to P4: connection point, T2, T3 ... output terminal, L1L, L1H ... connection line, LO ... output line, LG ... ground line, Δt ... fuel supply cycle.

Claims (13)

A power generation unit that generates power by supplying fuel and oxidant gas;
While supplying liquid fuel to the power generation unit side, a fuel supply unit in which the supply amount of the liquid fuel is adjustable,
A fuel vaporization section for vaporizing the liquid fuel supplied by the fuel supply section to supply gaseous fuel to the power generation section;
A temperature detection unit for detecting the temperature of the power generation unit;
A control unit that controls the temperature of the power generation unit to be constant by adjusting the amount of liquid fuel supplied by the fuel supply unit based on the temperature of the power generation unit detected by the temperature detection unit. Fuel cell system. The control unit approximately calculates an energy conversion efficiency in the power generation unit based on a power generation voltage of the power generation unit or a predetermined set voltage, and supplies the liquid fuel using the calculated energy conversion efficiency. The fuel cell system according to claim 1, wherein the amount is corrected. 3. The fuel cell system according to claim 2, wherein the control unit calculates energy conversion efficiency in the power generation unit in consideration of a power generation voltage of the power generation unit or a predetermined set voltage in addition to a power generation current of the power generation unit. . A current detection unit for detecting the generated current of the power generation unit;
The controller is
Based on the power generation current detected by the current detection unit, the fuel usage rate in the power generation unit is calculated, and the supply amount of the liquid fuel is calculated so that the calculated fuel usage rate is constant. ,
The final liquid fuel supply amount in consideration of the first fuel supply amount calculated based on the temperature of the power generation unit and the second fuel supply amount calculated based on the fuel utilization rate The fuel cell system according to any one of claims 1 to 3, wherein the fuel cell system is determined. The fuel cell system according to claim 4, wherein the control unit determines the final supply amount of the liquid fuel by selecting one of the first and second fuel supply amounts. 6. The fuel cell according to claim 5, wherein the control unit determines the final supply amount of the liquid fuel by selecting a smaller supply amount value from the first and second fuel supply amounts. 7. system. The fuel cell system according to claim 4, wherein the control unit periodically updates a set value of the fuel utilization rate. The control unit makes the temperature of the power generation unit constant by making the supply amount of the liquid fuel proportional to the time integral value and the time differential value of the difference between the set temperature and the detected temperature of the power generation unit. The fuel cell system according to any one of claims 1 to 3, wherein control is performed so as to become. The control unit performs control so that the temperature of the power generation unit becomes constant by making the supply amount of the liquid fuel proportional to a difference value between a set temperature and the detected temperature of the power generation unit. The fuel cell system according to any one of claims 1 to 3. The controller controls the temperature of the power generation unit to be constant by making the supply amount of the liquid fuel proportional to the time integral value of the difference between the set temperature and the detected temperature of the power generation unit. The fuel cell system according to any one of claims 1 to 3. The control unit controls the temperature of the power generation unit to be constant by making the supply amount of the liquid fuel proportional to the time differential value of the difference between the set temperature and the detected temperature of the power generation unit. The fuel cell system according to any one of claims 1 to 3. The fuel cell system according to any one of claims 1 to 3, further comprising a fuel tank that stores the liquid fuel. Equipped with a fuel cell system,
The fuel cell system includes:
A power generation unit that generates power by supplying fuel and oxidant gas;
While supplying liquid fuel to the power generation unit side, a fuel supply unit in which the supply amount of the liquid fuel is adjustable,
A fuel vaporization section for vaporizing the liquid fuel supplied by the fuel supply section to supply gaseous fuel to the power generation section;
A temperature detection unit for detecting the temperature of the power generation unit;
A control unit that controls the temperature of the power generation unit to be constant by adjusting the amount of liquid fuel supplied by the fuel supply unit based on the temperature of the power generation unit detected by the temperature detection unit. Electronics.

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