JP6185296B2 - Purge valve - Google Patents

Description

  The present invention relates to a purge valve used in a fuel cell system.

  Patent Document 1 discloses a purge valve in which an L-shaped water jacket channel is formed. Then, when starting the fuel cell system particularly in a low temperature environment such as below freezing point, the purge valve is warmed up by flowing cooling water through the purge valve. By doing so, even if a part of the purge passage is frozen, this freezing is eliminated.

Japanese Patent No. 4687679

  The inventors of the present invention are diligently researching the warm-up of the purge valve at the time of cold start. Various factors affect the flow rate of the cooling water that can flow to the purge valve. For example, it is affected by the flow rate that the cooling water pump can discharge at low temperature startup. It is also affected by the flow rate allocation with parts other than the purge valve that warm up (for example, the cathode pressure regulating valve). Due to such factors, the flow rate of the purge valve is determined. In the method of Patent Document 1, when the flow rate of cooling water flowing through the purge valve is small, sufficient warm-up performance cannot be obtained.

  The present invention has been made paying attention to such conventional problems. An object of the present invention is to provide a purge valve that can prevent malfunction due to freezing even when the flow rate of cooling water flowing through the purge valve is small.

  The present invention solves the above problems by the following means.

The present invention solves the above problems by the following means.
One aspect of the purge valve according to the present invention is a purge valve provided in the anode offgas flow path for purging the anode offgas from the fuel cell stack to the atmosphere. And a purge valve channel through which purge gas flows, a housing in which a water jacket channel through which cooling water for adjusting the temperature of the purge valve flows is formed, a valve body for opening and closing the purge valve channel and adjusting the purge gas amount, including. The water jacket flow path is connected to a cooling water flow path for flowing cooling water for cooling the upstream components. Further, the cross-sectional area of the water jacket channel is small in the cross-sectional area of the connected cooling water channel.

  According to this aspect, the channel cross-sectional area of the water jacket channel formed in the housing is smaller than the channel cross-sectional area of the connected cooling water channel. Therefore, the cooling water flowing through the water jacket flow path is faster than the cooling water flowing through the cooling water flow path. The higher the speed, the more the heat exchange at the interface between the cooling water and the flow path surface, and the higher the heat transfer coefficient, the easier it is for the heat of the cooling water to be transferred to the housing of the purge valve. Available to:

  Embodiments of the present invention and advantages of the present invention will be described in detail below with reference to the accompanying drawings.

FIG. 1 is a diagram illustrating a fuel cell system using a purge valve according to the present invention. FIG. 2 is a diagram illustrating a fuel cell stack. FIG. 3 is a schematic diagram for explaining the reaction of the electrolyte membrane in the fuel cell stack. FIG. 4 is an external perspective view of the purge valve. FIG. 5 is a longitudinal sectional view of the purge valve. FIG. 6 is a perspective view showing a water jacket channel formed in the housing. FIG. 7 is a plan view of the water jacket channel. FIG. 8 is a longitudinal sectional view showing the purge valve of the second embodiment.

  First, in order to facilitate understanding of the embodiment, a fuel cell system using a purge valve according to the present invention will be described with reference to FIG.

  The fuel cell system 1 is a power generation system that supplies pulsating anode gas to the fuel cell stack 100. The fuel cell system 1 includes a fuel cell stack 100, a cathode gas supply / discharge device 3, an anode gas supply / discharge device 4, a stack cooling device 6, and a controller 7.

  A plurality of power generation cells 10 are stacked on the fuel cell stack 100. The fuel cell stack 100 is supplied with the anode gas and the cathode gas, and generates electric power necessary for driving the vehicle (for example, electric power necessary for driving the motor).

  The cathode gas supply / discharge device 3 includes a cathode gas supply channel 31, a filter 32, a cathode compressor 33, a cathode gas discharge channel 35, and a cathode pressure regulating valve 36.

  The cathode gas supply channel 31 is a passage through which the cathode gas supplied to the fuel cell stack 100 flows.

  The filter 32 removes foreign matter from the air (outside air) as the cathode gas. The cathode gas that has passed through the filter 32 flows through the cathode gas supply channel 31.

  The cathode compressor 33 is disposed in the middle of the cathode gas supply channel 31.

  The cathode gas discharge channel 35 is a passage through which the cathode off gas discharged from the fuel cell stack 100 flows. The cathode gas discharge channel 35 is connected to the cathode discharge port 22b of the fuel cell stack 100, and the downstream end is opened to the atmosphere.

  The cathode pressure regulating valve 36 is disposed in the cathode gas discharge channel 35. The cathode pressure regulating valve 36 adjusts the cathode gas supplied from the cathode compressor 33 to a desired pressure. Since the structure of the cathode pressure regulating valve 36 is known, a detailed description is omitted, but a butterfly type valve element built in the housing is driven by a motor. The opening degree of the cathode pressure regulating valve 36 is controlled by the controller 7. A water jacket is formed in the cathode pressure regulating valve 36. As will be described later, by introducing cooling water into the water jacket, the cathode pressure regulating valve 36 is prevented from sticking due to freezing.

  The anode gas supply / discharge device 4 includes a high pressure tank 41, an anode gas supply channel 42, an anode pressure regulating valve 43, an anode gas discharge channel 45, a purge gas channel 46, a purge valve 47, and a buffer tank 400. .

  The high pressure tank 41 stores the anode gas supplied to the fuel cell stack 100 in a high pressure state.

  The anode gas supply channel 42 is a passage for supplying the anode gas of the high-pressure tank 41 to the fuel cell stack 100. The anode gas supply channel 42 is connected to the high-pressure tank 41 and the anode supply port 21 a of the fuel cell stack 100.

  The anode pressure regulating valve 43 is provided in the anode gas supply channel 42. The anode pressure regulating valve 43 adjusts the anode gas discharged from the high pressure tank 41 to a desired pressure. The anode pressure regulating valve 43 is an electromagnetic valve whose opening degree is adjusted continuously or stepwise. The opening degree of the anode pressure regulating valve 43 is controlled by the controller 7.

  The anode gas discharge channel 45 is connected to the anode discharge port 21 b of the fuel cell stack 100 and the buffer tank 400. The anode gas discharge channel 45 has a mixed gas (hereinafter referred to as “anode offgas”) of excess anode gas that has not been used in the electrode reaction and an inert gas such as nitrogen or water vapor that has permeated from the cathode side to the anode side. Flows).

  The buffer tank 400 temporarily stores the anode off gas that has flowed through the anode gas discharge passage 45. When the anode pressure inside the fuel cell stack 100 decreases, the anode gas in the buffer tank 400 flows backward and is supplied to the fuel cell stack 100.

  The purge gas passage 46 is connected to the anode gas discharge passage 45 and the cathode gas discharge passage 35.

  The purge valve 47 is provided in the purge gas flow path 46. The purge valve 47 is an electromagnetic valve that is adjusted to be fully open or fully closed. The purge valve 47 is controlled by the controller 7. When the purge valve 47 is opened, the anode off-gas in the buffer tank 400 flows through the purge gas passage 46, mixes with the cathode off-gas in the cathode gas discharge passage 35, and is discharged to the outside air. In this way, the anode off gas is mixed with the cathode off gas and discharged to the outside air, so that the anode gas concentration in the outside air exhaust gas is lower than the flammable concentration.

  Moreover, the anode gas concentration in the buffer tank 400 is adjusted by discharging the anode off-gas from the buffer tank 400 to the outside air. If the anode gas concentration (hydrogen concentration) in the buffer tank 400 is too low, the anode gas used for the electrode reaction is insufficient in the operation of supplying the anode gas in a pulsating manner. If it does in this way, while generating efficiency falls, there exists a possibility that a fuel cell may deteriorate. On the other hand, if the anode gas concentration (hydrogen concentration) in the buffer tank 400 is too high, the amount of the anode gas discharged to the outside air together with the inert gas in the anode off-gas through the purge gas flow path 46 increases. Gets worse. Therefore, the purge valve 47 is opened and closed so that the anode gas concentration in the buffer tank 400 becomes an appropriate value in consideration of power generation efficiency and fuel consumption.

  A water jacket is formed inside the purge valve 47 as will be described later, and cooling water for cooling the fuel cell stack 100 circulates. This prevents sticking due to freezing.

  The stack cooling device 6 is a device that cools the fuel cell stack 100 and maintains the fuel cell stack 100 at a temperature suitable for power generation. The stack cooling device 6 includes a cooling water circulation passage 61, a radiator 62, a bypass passage 63, a three-way valve 64, a cooling water pump 65, a PTC (Positive Temperature Coefficient) heater 66, and a cooling water pressure regulating valve passage. 67 and a cooling water purge valve flow path 68.

  The cooling water circulation passage 61 is a passage through which cooling water for cooling the fuel cell stack 100 circulates. The cooling water circulation passage 61 is connected to the cooling water supply port 23 a and the cooling water discharge port 23 b of the fuel cell stack 100. In the description below, the cooling water circulation passage 61 will be described with the cooling water discharge port 23b side as the upstream side and the cooling water supply port 23a side as the downstream side.

  The radiator 62 is provided in the cooling water circulation passage 61. The radiator 62 cools the cooling water discharged from the fuel cell stack 100.

  The bypass flow path 63 allows the cooling water to bypass the radiator 62. The bypass flow path 63 is connected to the cooling water circulation flow path 61 and the three-way valve 64.

  The three-way valve 64 is provided in the cooling water circulation passage 61 on the downstream side of the radiator 62. The three-way valve 64 switches the cooling water circulation path according to the temperature of the cooling water. Specifically, if the temperature of the cooling water is high, the three-way valve 64 switches so that the cooling water flows through the radiator 62. If the temperature of the cooling water is low, the three-way valve 64 switches so that the cooling water flows through the bypass channel 63.

  The cooling water pump 65 is provided in the cooling water circulation passage 61 on the downstream side of the three-way valve 64. The cooling water pump 65 circulates cooling water.

  The PTC heater 66 is provided in the bypass channel 63. The PTC heater 66 is energized when the fuel cell stack 100 is warmed up to raise the temperature of the cooling water.

  The cooling water pressure regulating valve channel 67 is a passage for introducing cooling water into a water jacket formed inside the cathode pressure regulating valve 36 in order to prevent the cathode pressure regulating valve 36 from being stuck due to freezing. The cooling water pressure regulating valve channel 67 includes a feed channel 671 and a return channel 672. The feed passage 671 is a passage that branches from the coolant circulation passage 61 on the downstream side of the coolant pump 65 and feeds coolant to the water jacket of the cathode pressure regulating valve 36. The return flow path 672 is a path for returning the cooling water discharged from the water jacket of the cathode pressure regulating valve 36.

  The cooling water purge valve flow path 68 is a passage for introducing cooling water into a water jacket formed inside the purge valve 47 in order to prevent the purge valve 47 from sticking due to freezing. The cooling water purge valve channel 68 includes a feed channel 681 and a return channel 682. The feed flow path 681 is a passage that feeds the cooling water returned from the cathode pressure regulating valve 36 to the water jacket of the cathode pressure regulating valve 36. The return flow path 682 is a path for returning the cooling water discharged from the water jacket of the cathode pressure regulating valve 36 to the cooling water circulation flow path 61 on the upstream side of the cooling water pump 65.

  The controller 7 periodically opens and closes the anode pressure regulating valve 43 to periodically increase and decrease the anode pressure. Such an operation that varies the pressure is called a pulsation supply operation. Further, the controller 7 adjusts the flow rate of the anode off gas discharged from the buffer tank 400 by adjusting the opening of the purge valve 38 so as to keep the anode gas concentration in the buffer tank 400 at a desired concentration.

  By performing the pulsation supply operation, an impurity gas such as nitrogen that has permeated from the cathode side to the anode side through the electrolyte membrane 111 can be pushed into the buffer tank 400. As a result, it is possible to suppress the impure gas from accumulating in the anode channel and hindering the electrode reaction, and stable power generation can be performed.

  2A and 2B are diagrams illustrating a fuel cell stack, FIG. 2A is an external perspective view, and FIG. 2B is an exploded view showing the structure of a power generation cell.

  As shown in FIG. 2A, the fuel cell stack includes a plurality of stacked power generation cells 10 and a current collecting plate 20. The fuel cell stack is a rectangular parallelepiped.

  The power generation cell 10 is a unit cell of a fuel cell. Each power generation cell 10 generates an electromotive voltage of about 1 volt (V). Details of the configuration of each power generation cell 10 will be described later.

  The current collecting plates 20 are a pair and are respectively arranged outside the plurality of stacked power generation cells 10. The current collecting plate 20 is formed of a gas impermeable conductive member such as dense carbon or a metal material.

  One current collecting plate 20 (the current collecting plate 20 on the left front side in FIG. 2A) has an anode supply port 21a, an anode discharge port 21b, a cathode supply port 22a, a cathode along the short side. A discharge port 22b, a cooling water supply port 23a, and a cooling water discharge port 23b are provided. In the present embodiment, the anode supply port 21a, the cooling water supply port 23a, and the cathode discharge port 22b are provided on the right side in the drawing. The cathode supply port 22a, the cooling water discharge port 23b, and the anode discharge port 21b are provided on the left side in the drawing.

  As a method of supplying hydrogen as anode gas to the anode supply port 21a, for example, a method of supplying hydrogen gas directly from a hydrogen storage device or a hydrogen-containing gas reformed by reforming a fuel containing hydrogen is supplied. There are methods. Examples of the hydrogen storage device include a high-pressure gas tank, a liquefied hydrogen tank, and a hydrogen storage alloy tank. Examples of the fuel containing hydrogen include natural gas, methanol, and gasoline. Air is generally used as the cathode gas supplied to the cathode supply port 22a.

  As shown in FIG. 2B, the power generation cell 10 includes an anode separator (anode bipolar plate) 12a and a cathode separator (cathode bipolar plate) on both surfaces of a membrane electrode assembly (MEA) 11. 12b is arranged.

  In the MEA 11, electrode catalyst layers 112 are formed on both surfaces of an electrolyte membrane 111 made of an ion exchange membrane. A gas diffusion layer (GDL) 113 is formed on the electrode catalyst layer 112.

  The electrode catalyst layer 112 is formed of carbon black particles on which platinum is supported, for example.

  The GDL 113 is formed of a member having sufficient gas diffusibility and conductivity, such as carbon fiber.

  The anode gas supplied from the anode supply port 21a flows through this GDL 113a, reacts with the anode electrode catalyst layer 112 (112a), and is discharged from the anode discharge port 21b.

  The cathode gas supplied from the cathode supply port 22a flows through this GDL 113b, reacts with the cathode electrode catalyst layer 112 (112b), and is discharged from the cathode discharge port 22b.

  The anode separator 12a is overlaid on one side of the MEA 11 (back side in FIG. 2B) via the GDL 113a and the seal 14a. The cathode separator 12b is stacked on one side of the MEA 11 (the surface in FIG. 2B) via the GDL 113b and the seal 14b. The seal 14 (14a, 14b) is a rubber-like elastic material such as silicone rubber, ethylene propylene diene monomer (EPDM), or fluorine rubber. The anode separator 12a and the cathode separator 12b are formed by press-molding a separator base made of metal such as stainless steel so that a reaction gas channel is formed on one surface and alternately arranged with a reaction gas channel on the opposite surface. A cooling water flow path is formed. As shown in FIG. 2B, the anode separator 12a and the cathode separator 12b are overlapped to form a cooling water flow path.

  The MEA 11, the anode separator 12a, and the cathode separator 12b are respectively formed with holes 21a, 21b, 22a, 22b, 23a, and 23b, which are overlapped to form an anode supply port (anode supply manifold) 21a and an anode discharge port. (Anode discharge manifold) 21b, cathode supply port (cathode supply manifold) 22a, cathode discharge port (cathode discharge manifold) 22b, cooling water supply port (cooling water supply manifold) 23a and cooling water discharge port (cooling water discharge manifold) 23b Is formed.

  In FIG. 2, the current collector plate 20 on the front side is provided with an anode supply port 21 a, an anode discharge port 21 b, a cathode supply port 22 a, a cathode discharge port 22 b, a cooling water supply port 23 a, and a cooling water discharge port 23 b. However, the present invention is not limited to this. For example, the anode outlet 21b, the cathode outlet 22b, and the cooling water outlet 23b may be provided on the current collecting plate 20 on the back side. Such a type is used in the anode gas pulsation supply system of FIG.

  FIG. 3 is a schematic diagram for explaining the reaction of the electrolyte membrane in the fuel cell stack.

The fuel cell stack 10 is supplied with reaction gas (hydrogen H ₂ and oxygen O ₂ in the air) to generate power. The fuel cell stack 10 is configured by stacking hundreds of membrane electrode assemblies (MEA) in which a cathode electrode catalyst layer and an anode electrode catalyst layer are formed on both surfaces of an electrolyte membrane. One of the MEAs is shown in FIG. Here, the cathode gas is supplied to the MEA (cathode in) and discharged from the diagonal side (cathode out), while the anode gas is supplied (anode in) and discharged from the diagonal side (anode out). An example is shown.

  In each membrane electrode assembly (MEA), the following reaction proceeds in the anode electrode catalyst layer and the cathode electrode catalyst layer according to the load to generate power.

As shown in FIG. 3B, the reaction of the above formula (1-2) proceeds as the reaction gas (oxygen O ₂ in the air) flows through the cathode flow path, and water vapor is generated. Then, the relative humidity increases on the downstream side of the cathode channel. As a result, the relative humidity difference between the cathode side and the anode side increases. With this relative humidity difference as the driving force, water is back-diffused and the anode upstream side is humidified. This moisture further evaporates from the MEA to the anode channel, and humidifies the reaction gas (hydrogen H ₂ ) flowing through the anode channel. Then, it is transported downstream of the anode and humidifies the MEA downstream of the anode. Also, the air in the cathode channel permeates the electrolyte membrane and enters the anode channel. Oxygen O ₂ in the air reacts with hydrogen H _{2 in} the anode flow path, but nitrogen N ₂ in the air is discharged without reacting. A mixed gas (anode off gas) of the inert gas such as nitrogen and water vapor that has permeated from the cathode side to the anode side in this way and the excess anode gas that has not been used for the electrode reaction flows into the buffer tank 400. .

  When the purge valve 47 is opened, the anode off-gas in the buffer tank 400 flows through the purge gas passage 46, mixes with the cathode off-gas in the cathode gas discharge passage 35, and is discharged to the outside air. In this way, the anode gas concentration in the buffer tank 400 is adjusted.

  If the operation of the fuel cell system is stopped and left in a sub-zero environment, the moisture in the anode off-gas may freeze and the operation of the purge valve 47 may be hindered. Therefore, in this embodiment, a water jacket is formed inside the purge valve 47. Then, cooling water for cooling the fuel cell stack 100 is circulated. In this way, sticking due to freezing is prevented. Hereinafter, a specific structure of the purge valve 47 will be described.

  FIG. 4 is an external perspective view of the purge valve.

  In the purge valve 47, a water jacket channel 480 described later is formed inside the housing 470. A feed flow path 681 of the cooling water purge valve flow path 68 is connected to one end of the water jacket flow path 480. A return flow path 682 of the cooling water purge valve flow path 68 is connected to the other end of the water jacket flow path 480.

  The housing 470 is formed with a bolt hole 470a. The hole 470a is formed so as to pass between an upper channel 481 and a lower channel 482 of a water jacket channel described later. The purge valve 47 is fixed to the casing of the fuel cell stack 100 or the like by a bolt that penetrates the bolt hole 470a.

  FIG. 5 is a longitudinal sectional view of the purge valve.

  The purge valve 47 includes a housing 470 and a valve body 475. In the housing 470, an inlet channel 471, an outlet channel 472, and a connection channel 473 are formed. The inlet channel 471 is formed below the housing 470. The outlet channel 472 is formed above the housing 470. A purge gas channel 46 is connected to the inlet channel 471 and the outlet channel 472. The connection channel 473 is formed by connecting the inlet channel 471 and the outlet channel 472. The connection channel 473 is narrower than the inlet channel 471 and the outlet channel 472. In this way, the flow velocity of the gas flowing through the connection channel 473 is sufficiently high, and the connection channel 473 can be raised against moisture against gravity. There is a seating surface 474 at the boundary between the connection channel 473 and the outlet channel 472. When the valve body 475 rises and separates from the seat surface 474, the connection channel 473 and the outlet channel 472 communicate with each other, and the purge gas flows from the inlet channel 471 → the connection channel 473 → the outlet channel 472, and the purge gas It is discharged to the flow path 46.

  As described above, the contact portion between the valve body 475 and the seat surface 474 is provided above the gravity direction, so that moisture hardly remains in the contact portion between the valve body 475 and the seat surface 474. Water may remain.

  In addition, moisture may remain on the wall surface of the channel. If purging with moisture frozen, there is a risk that sufficient purging cannot be performed.

  Therefore, in the present embodiment, the water jacket channel 480 (the upper channel 481 and the lower channel 482) through which the cooling water for cooling the fuel cell stack 100 flows is formed in the housing 470. The channel cross-sectional area of the lower channel 482 is smaller than the channel cross-sectional area of the upper channel 481.

  FIG. 6 is a perspective view showing a water jacket channel 480 formed in the housing 470.

  As described above, the water jacket channel 480 is formed inside the housing 470, but in FIG. 6, the housing 470 is omitted so that the shape of the water jacket channel 480 becomes clearer. It was.

  The water jacket channel 480 is connected to the feed channel 681 and the return channel 682 of the cooling water purge valve channel 68 so that the cooling water flows. The water jacket channel 480 includes an upper channel 481 and a lower channel 482.

  The upper channel 481 is formed by branching into two channels. The upper flow path 481 is narrower than the cooling water purge valve flow path 68. That is, the cross-sectional area of the upper flow path 481 is smaller than the cross-sectional area of the cooling water purge valve flow path 68. The flow passage cross-sectional area of the lower flow passage 482 is also smaller than the flow passage cross-sectional area of the cooling water purge valve flow passage 68. In addition, the total area of the channel cross-sectional area of the upper channel 481 and the channel cross-sectional area of the lower channel 482 is smaller than the channel cross-sectional area of the cooling water purge valve channel 68.

  FIG. 7 is a plan view of the water jacket channel, FIG. 7 (A) shows the upper channel, and FIG. 7 (B) shows the lower channel.

  As shown in FIG. 7A, the upper flow path 481 is formed by branching into two flow paths. These two channels have the same channel width. Cast iron of the housing 470 exists between the two flow paths, and the connection flow path 473 penetrates through the center.

  As shown in FIG. 7B, the lower flow path 482 has a shape in which an area through which the connection flow path 473 penetrates is cut out. The flow path width around this area is very narrow.

  Next, the effect of this embodiment is demonstrated.

  If the operation of the fuel cell system is stopped and left in a sub-zero environment, the moisture in the anode off-gas may freeze and the operation of the purge valve 47 may be hindered. Therefore, in this embodiment, a water jacket for introducing cooling water is formed inside the purge valve 47. With this configuration, the cooling water that has been heated in response to the heat generated by the fuel cell stack due to the activation of the fuel cell system is introduced into the purge valve 47, so that sticking due to freezing is prevented. In particular, in this embodiment, the cross-sectional area of each flow path of the water jacket flow path 480 is formed to be smaller than the cross-sectional area of the cooling water purge valve flow path. In particular, when the water jacket channel 480 is branched into a plurality, the total channel cross-sectional area is formed to be smaller than the channel cross-sectional area of the cooling water purge valve channel. Therefore, the cooling water flowing through the water jacket channel 480 is faster than the cooling water flowing through the cooling water purge valve channel. When the speed is faster, heat exchange at the interface between the cooling water and the flow path surface becomes more active, and the heat transfer coefficient becomes larger. This is because the heat exchange at the interface between the cooling water and the channel surface becomes more active and the heat transfer coefficient becomes larger when the cooling water flowing at the interface with the channel surface is in a turbulent state than in a laminar flow state. . Therefore, the heat of the cooling water is easily transmitted to the housing 470 of the purge valve 47. In particular, in this embodiment, the flow passage cross-sectional area of the lower flow passage 482 closest to the connection flow passage 473 is the smallest, the speed of the cooling water is the fastest, and heat exchange at the interface between the cooling water and the flow passage surface is active. become. For this reason, the heat of cooling water can be utilized efficiently.

  Note that if the flow path cross-sectional area of the water jacket flow path 480 is too narrow, pressure loss becomes excessive, which is not desirable. There is also the possibility of cavitation due to excessive flow velocity. When cavitation occurs, the heat transfer coefficient decreases. Therefore, in consideration of such points, the channel cross-sectional area of the water jacket channel 480 may be set as appropriate.

  Further, in the present embodiment, there is a cooling water passage (a cooling water pressure regulating valve passage 67, a cooling water purge valve passage 68) branched from the cooling water circulation passage 61 on the downstream side of the cooling water pump 65. The cathode pressure regulating valve 36 is disposed in the upstream side cooling water pressure regulating valve channel 67. A purge valve 47 is disposed in the cooling water purge valve flow path 68 on the downstream side.

  In such a case, the flow rate (cooling water passage cross-sectional area) of the cooling water flowing to the upstream component (here, the cathode pressure regulating valve 36) at the time of starting below zero is a predetermined part temperature at the time of starting assuming zero and the starting assuming the zero. It is set based on the predetermined cooling water temperature at the time.

  The temperature of the cooling water that has passed through the cathode pressure regulating valve 36 reaches the downstream part (purge valve 47) as the temperature decreases. Therefore, the temperature difference between the component (purge valve 47) and the cooling water temperature is smaller on the downstream side than on the upstream side. If the temperature difference is small, the heat exchange efficiency decreases.

  On the other hand, in this embodiment, the flow passage cross-sectional area of the water jacket flow passage 480 of the purge valve 47 is smaller than the flow passage cross-sectional area of the flow passage (cooling water pressure regulation valve flow passage 67) passing through the cathode pressure regulation valve 36. It was.

  In this way, the flow rate of the cooling water flowing through the water jacket channel 480 increases. If the flow rate of the cooling water increases, heat exchange at the interface between the cooling water and the flow path surface becomes active, and the heat transfer coefficient increases. Therefore, although the temperature has decreased through the cathode pressure regulating valve 36, the heat of the cooling water still having heat can be used efficiently.

  In the present embodiment, the connection channel 473 is thinner than the inlet channel 471 and the outlet channel 472 so that the flow velocity of the gas flowing through the connection channel 473 is sufficiently high. However, in such a configuration, when moisture is frozen in the connection flow path 473, there is a large effect of narrowing the flow path area, and there is a possibility that sufficient purge cannot be performed.

  Therefore, in this embodiment, the water jacket channel 480 is branched, the upper channel 481 is formed above the connection channel 473, and the lower channel 482 is formed below the connection channel 473. Since it did in this way, the connection flow path 473 is heated entirely, and the freezing in the connection flow path 473 is prevented.

  In addition, it is particularly desirable to prevent moisture from freezing at the contact portion between the seating surface 474 and the valve body 475. Therefore, in the present embodiment, the outlet channel 472 is formed below the seat surface portion of the connection channel 473. In this way, moisture easily flows down, and moisture hardly remains on the seating surface portion of the connection channel 473. However, with such a structure, the outlet channel 472 becomes an obstacle, and it is difficult to bring the upper channel 481 of the water jacket channel 480 close to the seat surface portion of the connection channel 473. Therefore, in the present embodiment, the upper channel 481 of the water jacket channel 480 is made thicker than the lower channel 482. By doing so, the heat capacity of the upper flow path 481 is increased, and the heat of the cooling water is easily transmitted to the seat surface portion even if it is away from the seat surface portion.

  In the present embodiment, a bolt hole 470 a is formed in the housing 470. The bolt hole 470 a passes between the upper channel 481 and the lower channel 482 of the water jacket channel 480. Since it is such a structure, the bolt hole 470a becomes an air layer (heat insulation part), and unnecessary diffusion of the heat of the cooling water is prevented. Therefore, the vicinity of the connection flow path 473 can be efficiently warmed by the heat of the cooling water.

  In the present embodiment, the cooling water discharged from the cooling water pump 65 is introduced into the cathode pressure regulating valve 36 and then supplied to the purge valve 47. Since the operation of the cathode pressure regulating valve 36 is controlled at the time of starting, it is necessary to eliminate the freezing of the cathode pressure regulating valve at an early stage. However, if the flow rate or temperature of the cooling water is increased unnecessarily, the fuel efficiency will deteriorate. Therefore, the flow rate and temperature of the cooling water are designed so that the requirements for the cathode pressure regulating valve 36 can be satisfied. The cathode pressure regulating valve 36 also includes a motor. Therefore, the cathode pressure regulating valve 36 is large in size.

  When the cooling water passes through the cathode pressure regulating valve 36, the temperature decreases, but still has heat. In this embodiment, the purge valve 47 is warmed up using such cooling water. In the system shown in FIG. 1, since there are two purge valves 47, the cooling water exiting from the cathode pressure regulating valve 36 is branched into two cooling water purge valve channels 68. Therefore, the flow rate of the cooling water flowing through the purge valve 47 is smaller than the flow rate of the cooling water flowing through the cathode pressure regulating valve 36. In the present embodiment, the temperature of the purge valve 47 flows through the cathode pressure regulating valve 36, and the purge valve 47 is warmed up by efficiently using cooling water with a low flow rate.

  Therefore, the flow velocity is increased by keeping the cross-sectional area of the water jacket flow path 480 of the purge valve 47 smaller than the cross-sectional area of the cooling water purge valve flow path. By doing in this way, the heat exchange in the interface of a cooling water and a flow-path surface can be made active, and the heat of a cooling water can be utilized efficiently.

  As described above, the cathode pressure regulating valve 36 is larger than the purge valve 47, and in setting the temperature and flow rate of the cooling water, the cooling water is first supplied in consideration of the cathode pressure regulating valve 36, and the heat that has not been used. As a result, the energy efficiency can be improved.

(Second Embodiment)
FIG. 8 is a longitudinal sectional view showing the purge valve of the second embodiment.

  In this embodiment, the upper channel 481 of the water jacket channel 480 is further branched. In the first embodiment, the upper flow path 481 is bifurcated into two on the left and right. In the second embodiment, the upper channel 481 is bifurcated on the left and right, and further on the upper and lower sides. The sum total of these channel cross-sectional areas is the same as or smaller than the upper channel of the first embodiment.

  With this configuration, the upper channel of the upper channel 481 can be brought closer to the seating surface portion of the connection channel 473. For this reason, it becomes easier to prevent the seat surface from freezing. Further, if the flow path cross-sectional area is reduced, the heat capacity is reduced, but it can be brought closer to the seating surface. In this respect as well, it becomes easy to prevent the seating surface from freezing. Further, the flow rate of the cooling water is increased by reducing the cross-sectional area of the flow path. Therefore, heat exchange at the interface between the cooling water and the flow path is activated. For this reason, the heat of cooling water can be utilized efficiently.

  The embodiment of the present invention has been described above. However, the above embodiment only shows a part of application examples of the present invention, and the technical scope of the present invention is limited to the specific configuration of the above embodiment. Absent.

  For example, in the above embodiment, the bolt hole formed in the housing serves as an air layer and functions as a heat insulating portion, but is not limited to such a structure. In addition, a hole may be formed or a heat insulating member may be present.

  The shape of the water jacket channel is merely an example.

  In the above embodiment, the cooling water is first supplied to the cathode pressure regulating valve and then to the purge valve. That is, the positional relationship between the cathode pressure regulating valve and the purge valve is in series. However, the positional relationship is not limited to this. The cooling water may be branched and allowed to flow to the cathode pressure regulating valve and to the purge valve. That is, the positional relationship between the cathode pressure regulating valve and the purge valve may be in a parallel state. Even if the above-described purge valve is applied to such a system, the purge valve can be efficiently warmed up by efficiently using the heat of the cooling water.

  The above embodiments can be appropriately combined.

47 Purge valve 470 Housing 471-473 Gas flow path 475 Valve body 480 Water jacket flow path 68, 681, 682 Cooling water flow path

Claims (8)

A purge valve provided in the anode off gas flow path for purging the anode off gas from the fuel cell stack to the atmosphere,
A housing in which a gas passage through which purge gas flows, a water jacket passage through which cooling water for adjusting the temperature of the purge valve flows, and
A valve body that opens and closes the gas flow path to adjust the purge gas amount;
Including
The water jacket flow path is connected to a cooling water flow path for flowing cooling water for cooling the upstream components;
The flow path cross-sectional area of the water jacket passage is smaller than the flow path cross-sectional area of the cooling water flow path,
Purge valve. The purge valve according to claim 1, wherein
The channel cross-sectional area of the water jacket channel is the smallest at the point closest to the gas channel,
Purge valve. The purge valve according to claim 1 or 2,
The water jacket channel branches into a plurality of channels so as to include a channel that passes the upstream side of the gas channel and a channel that passes the downstream side,
Purge valve. The purge valve according to claim 3,
The gas flow path is formed such that the purge gas flows upward from below in the direction of gravity,
The water jacket passage includes a flow path through the lower portion of the gas flow path, and a flow path through the upper,
Purge valve. The purge valve according to claim 4, wherein
The valve body abuts on the valve seat at the upper end of the gas flow path,
Minimum flow path cross-sectional area of the flow path through the upper portion of the gas flow path of the water jacket passage is larger than the minimum flow path cross-sectional area of the flow path through the bottom,
Purge valve. In the purge valve according to any one of claims 3 to 5,
Further comprising a heat insulating portion formed between the bifurcated the water jacket passage,
Purge valve. The purge valve according to claim 6, wherein
The heat insulating part is a hole through which a bolt is inserted.
Purge valve. The purge valve according to any one of claims 1 to 7,
The cooling water flow path is branched from a cooling water circulation flow path on the downstream side of the cooling water pump, a cooling water pressure regulation valve flow path provided with a cathode pressure regulation valve in the middle, and a purge valve in the middle of the cooling water pressure regulation valve flow path anda cooling water purge valve passage which is provided with,
The channel cross-sectional area of the water jacket channel is smaller than the channel cross-sectional area of the cooling water pressure regulating valve channel,
Purge valve.

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