JP5232451B2 - Control device for fuel cell system - Google Patents

Description

  The present invention relates to a control device for a fuel cell system.

2. Description of the Related Art Conventionally, in a fuel cell system including a fuel cell such as a solid polymer membrane fuel cell, a reactive gas (for example, hydrogen or air) supplied to the fuel cell in order to maintain the ionic conductivity of the solid polymer electrolyte membrane. ) Is mixed with water (humidified water) by a humidifier, etc., and further, reaction product water is generated by an electrochemical reaction when the fuel cell is operated. Therefore, the off-gas of the fuel cell, particularly the off-gas on the oxygen electrode side is It is a highly humid gas.
For this reason, in the fuel cell system according to an example of the above-described prior art, dew condensation may occur in various sensors or the like disposed in the flow path of the off gas due to the highly humid off gas discharged from the fuel cell. In this case, the sensor may be deteriorated or damaged. In particular, since the solid polymer membrane fuel cell described above has a normal operating temperature lower than the vaporization temperature of water, and the offgas is discharged as a gas with a high humidity and a large amount of water, the water in the offgas is discharged. There is a problem of easy condensation.

In order to solve such a problem, in the fuel cell system according to the above-described prior art, when the temperature of the fuel cell falls below a predetermined temperature after the operation of the fuel cell system is stopped, the fuel cell system is automatically activated. There is known a control method of a fuel cell system that starts up and supplies scavenging gas to the fuel cell (see, for example, Patent Document 1).
JP 2007-035389 A

By the way, in the control method of the fuel cell system according to the above prior art, it is necessary to operate a temperature sensor for detecting the temperature of the fuel cell even when the operation of the fuel cell system is stopped. In addition to this temperature sensor, As a result, there is a problem that power consumption by a timer or the like for controlling the detection timing by the temperature sensor increases.
Moreover, since scavenging is automatically executed according to the detection value output from the temperature sensor after the operation of the fuel cell system is stopped, noise accompanying scavenging is generated at an unexpected timing by an operator or the like. There is a problem that the operator or the like feels uncomfortable with the behavior of the fuel cell system.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a control device for a fuel cell system capable of preventing the occurrence of dew condensation while preventing excessive energy consumption after the system is stopped. And

  In order to solve the above problems and achieve the object, a control device for a fuel cell system according to a first aspect of the present invention includes a hydrogen supply source (for example, the fuel supply device 8 in the embodiment), an oxygen supply A source (for example, an S / C output controller 6 and a supercharger (S / C) 7 in the embodiment), an anode electrode supplied with hydrogen as an anode gas from the hydrogen supply source, and the oxygen supply source It has a cathode electrode supplied with oxygen as a cathode gas and an electrolyte, generates electricity by an electrochemical reaction between the anode gas and the cathode gas, discharges the anode off-gas from the anode electrode, and discharges the cathode off-gas from the cathode electrode A fuel cell system (for example, the fuel cell system 1a in the embodiment) including the stack (for example, the fuel cell 2 in the embodiment). A temperature sensor for detecting the temperature of the cathode offgas discharged from the cathode electrode (for example, the temperature sensor 34 and the upstream state sensor 41 in the embodiment), and the humidity of the cathode offgas discharged from the cathode electrode. Humidity sensors to be detected (for example, humidity sensor 35 in the embodiment, upstream state sensor 41) and external temperature sensors to detect the external temperature of the fuel cell system (for example, the outside air temperature sensor 16 in the embodiment) And determining whether or not water contained in the cathode offgas is condensed when the temperature of the cathode offgas is lowered based on detection values output from the sensors when the operation of the fuel cell system is stopped. When it is determined that condensation occurs, control means for executing control for reducing the humidity of the cathode offgas (for example, in the embodiment) A control unit 10) and.

Further , the control means executes scavenging control for allowing scavenging gas to flow through the cathode off-gas flow path.

Furthermore, the control apparatus for a fuel cell system according to the second aspect of the present invention includes a heater for heating the cathode off gas (for example, the heater 33 in the embodiment), and the control means controls the energization of the heater. Run.

Furthermore, in the control apparatus for a fuel cell system according to the third aspect of the present invention, the heater is provided in a state quantity sensor (for example, the pressure sensor 15 in the embodiment) that detects the state quantity of the cathode off gas. .

  According to the control device for a fuel cell system according to the first aspect, when the fuel cell system is stopped, water contained in the cathode offgas is condensed when the saturated water vapor amount is reduced as the temperature of the cathode offgas is reduced. Then, control (humidity reduction control) for reducing the humidity of the cathode offgas is executed only when it is determined that the humidity reduction control is prevented from being executed excessively every time the fuel cell system is stopped. In addition, it is possible to prevent dew condensation due to the cathode off gas at an appropriate timing after the fuel cell system is stopped, and to prevent the necessity of performing humidity reduction control when the fuel cell system is stopped. be able to.

Further , as control for reducing the humidity of the cathode offgas, for example, by performing scavenging control for allowing a relatively dry scavenging gas to flow through the cathode offgas flow path, the humidity of the cathode offgas can be reduced.

Furthermore, according to the control apparatus for the fuel cell system according to the second aspect, as the control for reducing the humidity of the cathode offgas, for example, by performing energization control on the heater that directly or indirectly increases the temperature of the cathode offgas. The amount of saturated water vapor in the cathode off gas can be increased to lower the humidity.

Furthermore, according to the control device for a fuel cell system according to the third aspect, since the heater is provided in the state sensor that detects the state quantity of the cathode off gas, an appropriate value is obtained according to the detection value output from the state sensor. Energization control can be performed.

Embodiments of a control device for a fuel cell system according to the present invention will be described below with reference to the accompanying drawings.
As shown in FIG. 1, for example, the control device 1 of the fuel cell system according to this embodiment includes a fuel cell 2, a current controller 3, a power storage device 4, a load 5, an S / C output controller 6, Among the supercharger (S / C) 7, the fuel supply device 8, the output current sensor 9, the controller 10, and the pipes 11, 12, 13, 14 connected to the fuel cell 2, the oxygen electrode side A fuel cell system 1a configured to include a heater built-in pressure sensor (pressure sensor) 15 provided in the outlet side pipe 14 and an outside air temperature sensor 16 that detects an external temperature (for example, outside air temperature). It is something to control.

The fuel cell 2 is mounted on a vehicle as a power source of a fuel cell vehicle or an electric vehicle, for example, and an electrolyte electrode structure in which a solid polymer electrolyte membrane is sandwiched between a hydrogen electrode and an oxygen electrode is further sandwiched between a pair of separators. A plurality of unillustrated fuel battery cells are stacked.
The inlet side pipe 11 connected to the hydrogen electrode of the fuel cell 2 is supplied with a fuel gas containing hydrogen gas from a fuel supply device 8 having a high-pressure hydrogen tank or the like, for example, and undergoes a catalytic reaction on the catalyst electrode of the hydrogen electrode. The ionized hydrogen moves to the oxygen electrode through a moderately humidified solid polymer electrolyte membrane, and electrons generated by this movement are taken out to an external circuit and used as DC electric energy. . For example, an oxidant gas such as oxygen or air is supplied from a supercharger (S / C) 7 to the inlet side pipe 12 connected to the oxygen electrode, and hydrogen ions, electrons, and oxygen react at the oxygen electrode. As a result, water is generated. Then, the so-called off-gas that has been reacted is discharged out of the system from the outlet side pipes 13 and 14 on both the hydrogen electrode side and the oxygen electrode side. In particular, a solid polymer electrolyte fuel cell normally has an operating temperature lower than the vaporization temperature of water, and the off-gas is discharged as a gas with a high humidity and a large amount of moisture.

  Here, a heater built-in pressure sensor (pressure sensor) 15 is attached to the outlet side pipe 14 on the oxygen electrode side, so that the pressure of the off-gas in the outlet side pipe 14 on the oxygen electrode side can be confirmed by this pressure sensor 15. It has become.

The supercharger 7 takes in air from the outside of the vehicle, for example, compresses it, and supplies this air as a reaction gas to the oxygen electrode of the fuel cell 2.
The rotational speed of a motor (not shown) for driving the supercharger 7 is based on a control command input from the controller 10, for example, an S / C output controller 6 having a PWM inverter by pulse width modulation (PWM). Is controlled by.

The generated current (output current) taken out from the fuel cell 2 is input to the current controller 3, and a plurality of capacitor cells, such as electric double layer capacitors and electrolytic capacitors, are connected to each other in series. A power storage device 4 made of a connected capacitor or the like is connected.
The fuel cell 2, the current controller 3, and the power storage device 4 are, for example, a traveling motor (not shown), a cooling device (not shown), an air conditioner (not shown), or the like of the fuel cell 2 or the power storage device 4, for example. It is connected in parallel to a load 5 composed of various auxiliary machines and an S / C output controller 6.

In this fuel cell system 1 a, the controller 10 includes, for example, the operating state of the vehicle, the concentration of hydrogen contained in the fuel gas supplied to the hydrogen electrode of the fuel cell 2, and the offgas discharged from the hydrogen electrode of the fuel cell 2. Is supplied from the supercharger 7 to the fuel cell 2 based on the concentration of hydrogen contained in the fuel cell 2, the power generation state of the fuel cell 2, for example, the inter-terminal voltage of each of the plurality of fuel cells, the output current extracted from the fuel cell 2, etc. A command value for the flow rate of air and a command value for the flow rate of the fuel gas supplied from the fuel supply device 8 to the fuel cell 2 are output, and the power generation state of the fuel cell 2 is controlled.
Therefore, a detection signal output from the output current sensor 9 that detects the current value of the output current extracted from the fuel cell 2 is input to the controller 10.
Further, the controller 10 controls the current value of the output current extracted from the fuel cell 2 by the current controller 3 based on the power generation command (FC output command value) for the fuel cell 2.

  For example, as shown in FIG. 2, the pressure sensor 15 includes a case 21 having a flange portion 22, and a bolt 23 is inserted into the flange portion 22 so as to be fastened and fixed to the mounting seat 14 a of the outlet side pipe 14. It has become.

A cylindrical portion 24 is provided on an end surface (for example, a lower surface) in the thickness direction of the case 21, and the cylindrical portion 24 is inserted into the through hole 14 b of the outlet side pipe 14 from the outside.
The inside of the cylindrical portion 24 is formed as a gas pressure detection chamber 25, and the gas pressure detection chamber 25 communicates with the outlet side pipe 14.
Further, a sealing material 26 is attached to the outer peripheral surface 25A of the cylindrical portion 24, and is in close contact with the inner peripheral wall of the through hole 14b of the outlet side pipe 14 to ensure airtightness.

  A circuit board 30 sealed with resin is provided in the case 21, and, for example, as shown in FIG. 3, a gauge resistor 32 and a flat plate-like shape arranged on the surface of a diaphragm 31 facing the gas pressure detection chamber 25. A heater 33 is connected to the circuit board 30.

The heater 33 is a PTC (positive temperature coefficient) thermistor made of, for example, barium titanate or the like, and arbitrarily sets the Curie temperature according to the material composition of the semiconductor ceramic mainly composed of barium titanate constituting the PTC thermistor. The heater 33 can be used as a constant temperature heating element by utilizing the property that the electric resistance increases rapidly from the Curie temperature.
That is, the PTC thermistor self-heats due to Joule heat when a voltage is applied to the PTC element, and when the temperature of the PTC element exceeds the Curie temperature, the resistance value of the PTC element increases logarithmically. As a result, the current supplied to the PTC element is reduced and the increase in power is suppressed, so that the heat generation temperature is lowered. And if the resistance value of a PTC element falls, since the electric current supplied to a PTC element will increase and electric power will increase again, heat_generation | fever temperature will increase. By repeating this series of operations, the PTC thermistor functions as a constant temperature heating element having a self-control function.

  A temperature sensor 34 for detecting the temperature in the gas pressure detection chamber 25 and a humidity sensor 35 for detecting the humidity in the gas pressure detection chamber 25 are disposed on the inner side surface 25A of the gas pressure detection chamber 25. Each sensor 34, 35 is connected to the circuit board 30 in the case 21.

For example, as shown in FIG. 2, in the outlet side pipe 14 on the oxygen electrode side to which the pressure sensor 15 is attached, the gas to be detected is located at an upstream position adjacent to the attachment site of the pressure sensor 15 in the flow direction of the gas to be inspected. An upstream state sensor 41 for detecting the temperature and humidity, that is, the off-gas temperature and off-gas humidity upstream of the pressure sensor 15 is attached.
The upstream side state sensor 41 is configured such that a base 42 is inserted and fixed in a through hole 14 c formed in the outlet side pipe 14, and a tip detection part 43 is inserted into the outlet side pipe 14. Note that a sealing material 44 is attached to the outer peripheral wall of the base portion 42 of the upstream side state sensor 41 to ensure a sealing property between the upstream side state sensor 41 and the through hole 14c.

The controller 10 is connected to an outside air temperature sensor 16, an upstream state sensor 41 attached to the outlet side pipe 14, a gauge resistor 32, a temperature sensor 34, and a humidity sensor 35 provided in the pressure sensor 15. At the same time, it is connected to the heater 33 of the pressure sensor 15.
Then, the controller 10 determines the temperature of the cathode offgas in the outlet side pipe 14 on the oxygen electrode side based on the detection values output from the sensors 16, 41, 34, and 35 when the operation of the fuel cell system 1a is stopped. When it is lowered, it is determined whether or not the water contained in the cathode off gas is condensed. When it is determined that the water is condensed, control for reducing the humidity of the cathode off gas is executed.

For example, the controller 10 determines that the temperature of the cathode off-gas, that is, the off-gas temperature upstream of the pressure sensor 15 output from the upstream state sensor 41 or the temperature in the gas pressure detection chamber 25 output from the temperature sensor 34 is the outside air temperature. It is determined whether or not condensation occurs when the temperature drops to a temperature substantially equal to the outside air temperature output from the sensor 16. When the determination result is “YES”, that is, when it is determined that there is a possibility of condensation, the heater 33 starts to be energized and the supercharger 7 is driven to drive the fuel cell. The scavenging is started to supply air as scavenging gas to the second oxygen electrode and cathode off-gas flow paths (that is, the oxygen-side outlet pipe 14).
When energizing the heater 33, the temperature detection value output from the temperature sensor 34 is set to a value within a predetermined temperature range corresponding to the threshold temperature TE (L / H) having a predetermined hysteresis. The energization amount of the heater 33 is controlled. At this time, the controller 10 controls the heater by, for example, feedback control with respect to the current value supplied to the heater 33, chopper control based on, for example, on / off operation of the switching element (that is, on / off switching control). 33 is controlled.

  The control device 1 of the fuel cell system according to this embodiment has the above-described configuration. Next, the operation of the control device 1 of the fuel cell system, particularly the operation when the operation of the fuel cell system 1a is stopped will be described.

First, for example, in step S01 shown in FIG. 4, the outside air temperature output from the outside air temperature sensor 16, the temperature of the cathode off gas, for example, the off gas temperature upstream of the pressure sensor 15 output from the upstream state sensor 41, The humidity in the gas pressure detection chamber 25 output from the humidity sensor 35 is acquired.
In step S02, for example, when the cathode off-gas temperature drops to a temperature substantially equal to the outside air temperature based on the outside air temperature and the humidity in the gas pressure detection chamber 25, the relative humidity is a predetermined target relative humidity (< 100%), a humidity threshold required for a predetermined temperature range corresponding to a threshold temperature TE (L / H) having a predetermined hysteresis described later (for example, threshold humidity HY having a predetermined hysteresis) (L / H)) is acquired by, for example, a map search for a predetermined map.

In step S03, condensation can occur when the cathode offgas temperature, that is, the upstream offgas temperature of the pressure sensor 15 output from the upstream state sensor 41, has dropped to a temperature substantially equal to the outside air temperature. It is determined whether or not there is sex.
When the determination result is “NO”, the series of processes is terminated.
On the other hand, if this determination is “YES”, the flow proceeds to step S 04.
In step S04, the heater 33 starts to be energized, and the supercharger 7 is driven to flow the oxygen electrode and cathode off-gas flow paths of the fuel cell 2 (that is, the oxygen-side outlet-side pipe 14). ) Starts scavenging to supply air as scavenging gas.

In step S05, the detection room temperature output from the temperature sensor 34, that is, the temperature in the gas pressure detection room 25 is a high side threshold temperature TE (H) of the threshold temperature TE (L / H) having a predetermined hysteresis. It is determined whether it is higher (for example, an appropriate value of 0 ° C. or more and 5 ° C. or less, such as 5 ° C.).
If this determination is “NO”, the flow proceeds to step S 07 described later.
On the other hand, if this determination is “YES”, the flow proceeds to step S 06.
In step S06, the energization current to the heater 33 is decreased. Thereby, by reducing the temperature in the gas pressure detection chamber 25, a target temperature within a desired temperature range is secured, and excessive power consumption is prevented.

In step S07, the detected temperature is a low threshold temperature TE (L) (for example, an appropriate value between 0 ° C. and 5 ° C.) of the threshold temperature TE (L / H) having a predetermined hysteresis. , 0 ° C., etc.).
If this determination is “NO”, the flow proceeds to step S 09 described later.
If this determination is “YES”, the flow proceeds to step S08.
In step S08, the energization current to the heater 33 is increased. As a result, the target temperature within a desired temperature range is secured by increasing the temperature in the gas pressure detection chamber 25, and the occurrence of condensation in the pressure sensor 15 is more reliably prevented.
In step S09, the energization current to the heater 33 at this time is maintained.

In step S10, it is determined whether or not the detected indoor humidity output from the humidity sensor 35, that is, the humidity in the gas pressure detecting chamber 25 is equal to or lower than a threshold humidity HY (L / H) having a predetermined hysteresis. .
If the determination result is “NO”, that is, if the detected indoor humidity is higher than the predetermined high-side threshold humidity HY (H), the process returns to step S05 described above.
On the other hand, if the determination result is “YES”, that is, if the detected indoor humidity is equal to or lower than the predetermined low-side threshold humidity HY (L), the process proceeds to step S11.
In step S11, the energization of the heater 33 and the execution of scavenging are stopped, and the series of processes is terminated.

As described above, according to the control device 1 of the fuel cell system according to the present embodiment, when the operation of the fuel cell system 1a is stopped, the cathode is turned off when the saturated water vapor amount decreases as the cathode offgas temperature decreases. Since control (humidity reduction control) for reducing the humidity of the cathode offgas is executed only when it is determined that the water contained in the offgas may condense, for example, when the operation of the fuel cell system 1a is stopped, it is excessive. It is possible to prevent the occurrence of condensation due to cathode offgas at an appropriate timing after the operation of the fuel cell system 1a is stopped, and to prevent the fuel cell system 1a from operating. At this time, it is possible to prevent the necessity of executing the humidity reduction control.
Since the moisture in the off-gas can be prevented from condensing in the gas pressure detection chamber 25, the condensed water comes into contact with the diaphragm 31 in the gas pressure detection chamber 25, and the condensed water is frozen. The durability of the diaphragm 31 can be enhanced, and the pressure detection accuracy by the gauge resistor 32 can be enhanced.

In addition, while preventing excessive energy consumption in the heater 33, for example, by providing a device for supplying a dedicated gas for drying the inside of the gas pressure detection chamber 25, the device configuration is complicated and enlarged. Preventing the occurrence of dew condensation on the diaphragm 31 and further preventing the pressure sensor 15 from being damaged, deteriorated, and lowered in detection accuracy due to freezing of condensed water in the diaphragm 31 after the fuel cell system 1a is stopped. Can do.
When the heater 33 is turned on, the energization amount of the heater 33 is set such that the temperature in the gas pressure detection chamber 25 becomes a value within a predetermined range corresponding to the threshold temperature TE (L / H) having a predetermined hysteresis. Therefore, it is possible to prevent dew condensation from newly occurring due to the gas to be detected that flows into the gas pressure detection chamber 25.

  In the above-described embodiment, energization and scavenging to the heater 33 are executed as control for reducing the humidity of the cathode offgas in step S04. However, the present invention is not limited to this. Only one of the scavenging may be executed.

  In the above-described embodiment, in step S03, condensation occurs when the upstream off-gas temperature of the pressure sensor 15 output from the upstream-side state sensor 41 decreases to a temperature substantially equal to the outside air temperature. However, the present invention is not limited to this. For example, as the temperature of the cathode off gas, the temperature in the gas pressure detection chamber 25 output from the temperature sensor 34 is substantially equal to the outside air temperature. It may be determined whether or not there is a possibility that dew condensation occurs when the pressure decreases.

  In the above-described embodiment, in step S10, the humidity detection value output from the humidity sensor 35, that is, the humidity in the gas pressure detection chamber 25 is equal to or lower than the threshold humidity HY (L / H) having a predetermined hysteresis. However, the present invention is not limited to this, and the humidity detection value output from the upstream-side state sensor 41, that is, the off-gas humidity of the cathode off-gas upstream of the pressure sensor 15 has a predetermined hysteresis. You may determine whether it is below threshold humidity HY (L / H).

  In the above-described embodiment, in step S05 and step S07, the detection chamber temperature output from the temperature sensor 34, that is, the temperature in the gas pressure detection chamber 25, and the threshold temperature TE (H / However, the present invention is not limited to this. For example, the heater 33 is provided with a temperature sensor, and the temperature detection value output from the temperature sensor, that is, the temperature of the heater 33 or the temperature of the diaphragm 31, and a predetermined hysteresis are obtained. The threshold temperature TE (H / L) may be compared.

  In the above-described embodiment, the heater 33 is a PTC thermistor. However, the heater 33 is not limited to this. Other heaters such as a heater made of a linear material having a large thickness may be used. For example, a conductive pattern formed on the surface of the diaphragm 31 by printing and firing a conductive resistor may be used as a part of the conductor pattern of the electric circuit. An eggplant heater may be used.

The control function executed by the controller 10 may be executed by a microcomputer or IC (not shown) mounted on the circuit board 30.
Further, even if the variation in the detection sensitivity of the pressure sensor 15 is corrected based on the temperature in the gas pressure detection chamber 25 detected by the temperature sensor 34 and the relative humidity in the gas pressure detection chamber 25 detected by the humidity sensor 35. Good.

  In the embodiment described above, energization to the heater 33 provided in the pressure sensor 15 is started as control for reducing the humidity of the cathode offgas. However, the present invention is not limited to this, and other sensors such as oxygen Energization of a heater built in a gas sensor or the like provided for confirming that hydrogen gas is not discharged from the pole-side outlet pipe 14 may be started.

It is a block diagram of the control apparatus of the fuel cell system which concerns on one Embodiment of this invention. It is a block diagram of the control apparatus of the fuel cell system which concerns on one Embodiment of this invention. It is a perspective view of a diaphragm, gauge resistance, and heater of a built-in pressure sensor according to an embodiment of the present invention. 3 is a flowchart showing the operation of the control device for the fuel cell system according to one embodiment of the present invention, particularly the operation when the fuel cell system is stopped.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Control apparatus 1a of fuel cell system Fuel cell system 2 Fuel cell (stack)
6 S / C output controller (oxygen supply source)
7 Supercharger (S / C) (Oxygen supply source)
8 Fuel supply system (hydrogen supply source)
10 Controller (control means)
15 Pressure sensor (state quantity sensor)
16 Outside air temperature sensor (external temperature sensor)
33 Heater 34 Temperature sensor 35 Humidity sensor 41 Upstream state sensor (temperature sensor, humidity sensor)

Claims (3)

A hydrogen source, an oxygen source,
An anode electrode supplied with hydrogen as an anode gas from the hydrogen supply source, a cathode electrode supplied with oxygen as a cathode gas from the oxygen supply source, and an electrolyte, and by an electrochemical reaction between the anode gas and the cathode gas A fuel cell system comprising a stack that generates electric power, discharges anode off-gas from the anode electrode, and discharges cathode off-gas from the cathode electrode,
A temperature sensor for detecting the temperature of the cathode offgas discharged from the cathode electrode;
A humidity sensor for detecting the humidity of the cathode offgas discharged from the cathode electrode;
An external temperature sensor for detecting an external temperature of the fuel cell system;
When operation of the fuel cell system is stopped, based on detection values output from the sensors, it is determined whether or not water contained in the cathode offgas is condensed when the temperature of the cathode offgas is reduced to an outside temperature. When it is determined that condensation occurs, a control means is provided for executing control for reducing the humidity of the cathode offgas by causing a scavenging gas composed of outside air to flow through the flow path of the cathode offgas. Control device for fuel cell system. A heater for heating the cathode offgas;
2. The control device for a fuel cell system according to claim 1, wherein the control unit performs energization control on the heater as control for reducing the humidity of the cathode off gas . 3. The control device of a fuel cell system according to claim 2 , wherein the heater is provided in a state quantity sensor that detects a state quantity of the cathode off gas.

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